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All 16 and 32Gbs switches are NVMe-ready.\r\n<span style=\"font-weight: bold;\">Connectrix Switches available:</span>\r\n<ul><li>DS-6505B: Up to 24 ports, 16Gbps max</li><li>DS-6510B: Up to 48 ports, 16Gbps max</li><li>DS-6520B: Up to 96 ports, 16Gbps max</li><li>DS-6610B: Up to 24 ports, 32Gbps max</li><li>DS-6620B: Up to 64 ports, 32Gbps max</li><li>DS-6630B: Up to 128 ports, 32Gbps max</li><li>MP-7800B: Up to 16 8Gbs ports and 6 GigE ports</li><li>MP-7810B:&nbsp; Up to 12 32Gbs ports and six 1/10GbE SFP+ ports</li><li>MP-7840B: Up to 24 16Gbs port plus 16 1/10 GigE and 2 40 GigE ports</li><li>MDS-9132T: Up to 32 ports, 32Gbps max</li><li>MDS-9148S: Up to 48 ports, 16Gbps max</li><li>MDS-9396S: Up to 96 ports, 16Gbps max</li><li>MDS-9148T: Up to 48 ports, 32Gbps max</li><li>MDS-9396T: Up to 96 ports, 32Gbps max</li><li>MDS-9250i: Up to 40 FC ports, 2 x 10 GigE ports, 8 FCoE ports and 16Gbps max</li><li>CNX-S4048: Up to 54 ports, 48 10 GbE SFP capable ports and six 40 GbE QSFP capable ports</li></ul>\r\n<span style=\"font-weight: bold;\">Key features:</span>\r\n<ul><li>Offers Fibre Channel connectivity of up to 32 gigabits per second and Gigabit Ethernet speeds up to 40 GbE</li><li>Scales from 8 to 128 ports per system</li><li> Uses redundant components and multipath deployment to ensure high availability and failover</li><li>Monitors your storage networking environment automatically with resilient networking features</li></ul>","shortDescription":"Bring high bandwidth and zero downtime to your storage network with Connectrix switches.","type":"Hardware","isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":15,"sellingCount":9,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Dell EMC Connectrix Switches","keywords":"","description":"Bring high bandwidth and zero downtime to your storage network with Connectrix switches. <span style=\"font-weight: bold;\">Connectrix B-Series, Connectrix MDS Series and Connectrix D-Series</span> offer you a range of enterprise, departmental, edge switches and","og:title":"Dell EMC Connectrix Switches","og:description":"Bring high bandwidth and zero downtime to your storage network with Connectrix switches. <span style=\"font-weight: bold;\">Connectrix B-Series, Connectrix MDS Series and Connectrix D-Series</span> offer you a range of enterprise, departmental, edge switches and","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Dell_EMC_Connectrix_Switches.jpg"},"eventUrl":"","translationId":4775,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":513,"title":"Networking","alias":"networking","description":" Networking hardware, also known as network equipment or computer networking devices, are electronic devices which are required for communication and interaction between devices on a computer network. Specifically, they mediate data transmission in a computer network. Units which are the last receiver or generate data are called hosts or data terminal equipment.\r\nNetworking devices may include gateways, routers, network bridges, modems, wireless access points, networking cables, line drivers, switches, hubs, and repeaters; and may also include hybrid network devices such as multilayer switches, protocol converters, bridge routers, proxy servers, firewalls, network address translators, multiplexers, network interface controllers, wireless network interface controllers, ISDN terminal adapters and other related hardware.\r\nThe most common kind of networking hardware today is a copper-based Ethernet adapter which is a standard inclusion on most modern computer systems. Wireless networking has become increasingly popular, especially for portable and handheld devices.\r\nOther networking hardware used in computers includes data center equipment (such as file servers, database servers and storage areas), network services (such as DNS, DHCP, email, etc.) as well as devices which assure content delivery.\r\nTaking a wider view, mobile phones, tablet computers and devices associated with the internet of things may also be considered networking hardware. As technology advances and IP-based networks are integrated into building infrastructure and household utilities, network hardware will become an ambiguous term owing to the vastly increasing number of network capable endpoints.","materialsDescription":" <span style=\"font-weight: bold;\">What is network equipment?</span>\r\nNetwork equipment - devices necessary for the operation of a computer network, for example: a router, switch, hub, patch panel, etc. You can distinguish between active and passive network equipment.\r\n<span style=\"font-weight: bold;\">What is an active network equipment?</span>\r\nActive networking equipment is equipment followed by some “smart” feature. That is, a router, switch (switch), etc. are active network equipment.\r\n<span style=\"font-weight: bold;\">What is passive network equipment?</span>\r\nPassive network equipment - equipment not endowed with &quot;intellectual&quot; features. For example - cable system: cable (coaxial and twisted pair (UTP/STP)), plug / socket (RG58, RJ45, RJ11, GG45), repeater (repeater), patch panel, hub (hub), balun (balun) for coaxial cables (RG-58), etc. Also, passive equipment can include mounting cabinets and racks, telecommunication cabinets.\r\n<span style=\"font-weight: bold;\">What are the main network components?</span>\r\nThe main components of the network are workstations, servers, transmission media (cables) and network equipment.\r\n<span style=\"font-weight: bold;\">What are workstations?</span>\r\nWorkstations are network computers where network users implement application tasks.\r\n<span style=\"font-weight: bold;\">What are network servers?</span>\r\nNetwork servers - hardware and software systems that perform the functions of controlling the distribution of network shared resources. A server can be any computer connected to the network on which the resources used by other devices on the local network are located. As the server hardware, fairly powerful computers are used.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Networking.png"}],"characteristics":[],"concurentProducts":[{"id":5130,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Kemp_logo.png","logo":true,"scheme":false,"title":"Kemp LoadMaster 3000","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"kemp-loadmaster-3000","companyTitle":"Kemp","companyTypes":["vendor"],"companyId":8201,"companyAlias":"kemp","description":"<span style=\"font-weight: bold; \">LM-3000 Server Load Balancer</span> - The LoadMaster 3000 provides Intelligent Application Delivery for Growing Organizations and features:\r\n<ul><li>4x GbE ports</li><li>1.7 Gbps L4 balancer throughput</li><li>SSL TPS (2K Keys): 1,000</li><li>SSL TPS (1K Keys): 2,000</li><li>Servers Supported: 1,000 Physical /1,000 Virtual</li><li>L4 Concurrent Connections: 8,600,000</li></ul>\r\nAgile organizations require end-to-end technology deployments that can support them as their application performance requirements grow. Kemp’s LoadMaster 3000 delivers comprehensive performance scaling to 1.7 Gbps application throughput and 1000 SSL transactions per second (TPS) combined with content switching, data compression and caching to meet the needs of dynamic, expanding infrastructures.\r\nThe LoadMaster 3000 is an essential component to include for high availability of critical line of business applications, internet facing web services and corporate intranets in small to medium sized deployments.\r\nCombining the latest advancements in Layer 4 to Layer 7 application delivery technology with features such as single sign-on, LoadMaster is the ADC of choice for providing high availability services across a wide range of application workloads.","shortDescription":"LM-3000 is an essential component to include for high availability of critical line of business applications, internet facing web services and corporate intranets in small to medium sized deployments.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":13,"sellingCount":15,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Kemp LoadMaster 3000","keywords":"","description":"<span style=\"font-weight: bold; \">LM-3000 Server Load Balancer</span> - The LoadMaster 3000 provides Intelligent Application Delivery for Growing Organizations and features:\r\n<ul><li>4x GbE ports</li><li>1.7 Gbps L4 balancer throughput</li><li>SSL TPS (2K Keys","og:title":"Kemp LoadMaster 3000","og:description":"<span style=\"font-weight: bold; \">LM-3000 Server Load Balancer</span> - The LoadMaster 3000 provides Intelligent Application Delivery for Growing Organizations and features:\r\n<ul><li>4x GbE ports</li><li>1.7 Gbps L4 balancer throughput</li><li>SSL TPS (2K Keys","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Kemp_logo.png"},"eventUrl":"","translationId":5131,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":321,"title":"Workload Scheduling and Automation Software","alias":"workload-scheduling-and-automation-software","description":"","materialsDescription":"","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Workload_Scheduling_and_Automation_Software.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4620,"logoURL":"https://old.roi4cio.com/fileadmin/content/u250x-ROI4CIO.jpg","logo":true,"scheme":false,"title":"WiJungle U250X (NextGen Firewall/UTM + Web Application Firewall + Hotspot Gateway + Load Balancer Router + VPN Router) With 3 Years License ","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"wijungle-u35-nextgen-firewallutm-appliance-web-application-firewall-appliance-hotspot-gateway-appliance-load-balancer-router-vpn-router-with-3-years-license","companyTitle":"WiJungle","companyTypes":["supplier","vendor"],"companyId":7007,"companyAlias":"wijungle","description":"<p><span class=\"c-message__body\" data-qa=\"message-text\">WiJungle seamlessly manages the network, internet and security of different business verticals like Enterprises, Education, Hospitality, Healthcare, Retail, Transport, Smart City, Defence, Residential Estates, Events etc. across the globe.<br />The product is available in 30+ different models to serve wide range of concurrent users with throughput range from 3.2 Gbps to 240 Gbps.<br /></span><br />It offers features like</p>\r\n<ul>\r\n<li>Access/Interface Management</li>\r\n<li>Network Management</li>\r\n<li>User/Guest Management</li>\r\n<li>BandWidth Management</li>\r\n<li>Quality Of Service</li>\r\n<li>Data Leakage Prevention</li>\r\n<li>Content Filtering</li>\r\n<li>Load Balancing</li>\r\n<li>High Availability</li>\r\n<li>Gateway Anti-Virus</li>\r\n<li>Anti-Spam</li>\r\n<li>Web Server Protection</li>\r\n<li>Sandbox</li>\r\n<li>Advance Threat Protection</li>\r\n<li>Intrusion Prevention System</li>\r\n<li>Virtual Private Network</li>\r\n<li>Vulnerability Assessment</li>\r\n<li>Intuitive &amp; Location Aware Captive Portals</li>\r\n<li>SMS Gateway Integration</li>\r\n<li>Social Media Engagement/Advertisement option</li>\r\n<li>Feedback Management</li>\r\n<li>User Logging</li>\r\n<li>Reporting and Analytics</li>\r\n<li>Prepaid/Postpaid Billing</li>\r\n<li>Voucher Management</li>\r\n<li>PMS/HIS Integration</li>\r\n<li>AP/Device Management</li>\r\n<li>Alert Management</li>\r\n</ul>\r\n<p>&nbsp;</p>","shortDescription":"WiJungle is a Unified Network Security Gateway Appliance that combinedly serves as NextGen Firewall/Unified Threat Management, Web Application Firewall, Hotspot Gateway, Vulnerability Assessment etc.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":1,"sellingCount":19,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"WiJungle U250X (NextGen Firewall/UTM + Web Application Firewall + Hotspot Gateway + Load Balancer Router + VPN Router) With 3 Years License ","keywords":"","description":"<p><span class=\"c-message__body\" data-qa=\"message-text\">WiJungle seamlessly manages the network, internet and security of different business verticals like Enterprises, Education, Hospitality, Healthcare, Retail, Transport, Smart City, Defence, Residential Est","og:title":"WiJungle U250X (NextGen Firewall/UTM + Web Application Firewall + Hotspot Gateway + Load Balancer Router + VPN Router) With 3 Years License ","og:description":"<p><span class=\"c-message__body\" data-qa=\"message-text\">WiJungle seamlessly manages the network, internet and security of different business verticals like Enterprises, Education, Hospitality, Healthcare, Retail, Transport, Smart City, Defence, Residential Est","og:image":"https://old.roi4cio.com/fileadmin/content/u250x-ROI4CIO.jpg"},"eventUrl":"","translationId":4620,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":443,"title":"Application Delivery Controller (load balancer) - appliance","alias":"application-delivery-controller-load-balancer-appliance","description":" Application Delivery Controllers are the next generation of load balancers, and are typically located between the firewall/router and the web server farm. An application delivery controller is a network device that helps sites direct user traffic to remove excess load from two or more servers. In addition to providing Layer 4 load balancing, ADCs can manage Layer 7 for content switching, and also provide SSL offload and acceleration. They tend to offer more advanced features such as content redirection as well as server health monitoring. An Application delivery controller may also be known as a Web switch, URL switch, Web content switch, content switch and Layer 7 switch.\r\nToday, advanced application delivery controllers and intelligent load balancers are not only affordable, but the consolidation of Layer 4-7 load balancing and content switching, and server offload capabilities such as SSL, data caching and compression provides companies with cost-effective out-of-the-box infrastructure.\r\nFor enterprise organizations (companies with 1,000 or more employees), integrating best-of-breed network infrastructure is commonplace. However best-of-breed does not equate with deploying networks with enterprise-specific features and expensive products, but rather, deploying products that are purpose-built, with the explicit features, performance, reliability and scalability created specifically for the companies of all sizes.\r\nIn general, businesses of all sizes are inclined to purchase “big brand” products. However, smaller vendors that offer products within the same category can provide the optimal performance, features and reliability required, with the same benefits - at a lower cost.\r\nFor the enterprise market, best-of-breed comes with a high Total Cost of Ownership (TCO), since deploying products from various manufacturers requires additional training, maintenance and support. Kemp can help SMBs lower their TCO, and help them build reliable, high performance and scalable web and application infrastructure. Kemp products have a high price/performance value for SMBs. Our products are purpose-built for SMB businesses for dramatically less than the price of “big name” ADC and SLB vendors who are developing features that enterprise customers might use.","materialsDescription":" <span style=\"font-weight: bold;\">What are application delivery controllers?</span>\r\nApplication Delivery Controllers (ADCs) are the next stage in the development of server load balancing solutions. ADCs allow you to perform not only the tasks of balancing user requests between servers, but also incorporate mechanisms that increase the performance, security and resiliency of applications, as well as ensure their scalability.\r\n<span style=\"font-weight: bold;\">And what other possibilities do application controllers have?</span>\r\nIn addition to the function of uniform distribution of user requests, application delivery controllers have many other interesting features. They can provide around-the-clock availability of services, improve web application performance up to five times, reduce risks when launching new services, protect confidential data, and publish internal applications to the outside with secure external access (a potential replacement for outgoing Microsoft TMG).\r\nOne of the most important functions of application delivery controllers, which distinguish them from simple load balancers, is the presence of a functional capable of processing information issued to the user based on certain rules.\r\n<span style=\"font-weight: bold;\">What are the prerequisites for implementing application delivery controllers in a particular organization?</span>\r\nA number of factors can determine the criteria for deciding whether to implement application controllers in your organization. First, this is the poor performance of web services, which is a long download of content, frequent hangs and crashes. Secondly, such a prerequisite can be interruptions in the work of services and communication channels, expressed in failures in the transmitting and receiving equipment that ensures the operation of the data transmission network, as well as failures in the operation of servers.\r\nIn addition, it is worth thinking about implementing application delivery controllers if you use Microsoft TMG or Cisco ACE products, since they are no longer supported by the manufacturer. A prerequisite for the implementation of ADC may be the launch of new large web projects, since this process will inevitably entail the need to ensure the operability of this web project with the maintenance of high fault tolerance and performance.\r\nAlso, controllers are needed when you need to provide fault tolerance, continuous availability and high speed of applications that are consolidated in the data center. A similar situation arises when it is necessary to build a backup data center: here you also need to ensure fault tolerance between several data centers located in different cities.\r\n<span style=\"font-weight: bold;\">What are the prospects for the introduction of application controllers in Russia and in the world?</span>\r\nGartner's research shows that there have recently been marked changes in the market for products that offer load balancing mechanisms. In this segment, user demand shifts from servers implementing a simple load balancing mechanism to devices offering richer functionality.\r\nGartner: “The era of load balancing has long gone, and companies need to focus on products that offer richer application delivery functionality.”\r\nIn Russia, due to the specifics of the internal IT market, application controllers are implemented mainly because of the presence of some specific functionality, and not because of the comprehensive solution for delivering applications in general, which this product offers. The main task for which application delivery controllers are now most often sold is the same load balancing function as before.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Application_Delivery_Controller_load_balancer_appliance.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":475,"title":"Network Management - Hardware","alias":"network-management-hardware","description":" Your business is much more than just a machine that dispenses products or services in exchange for money. It’s akin to a living and breathing thing. Just as with the human body, in business, all the parts are interconnected and work together to move things forward.\r\nIf a company’s management is the brain, then its employees are the muscles. Muscles don’t work without the oxygen carried to them by the blood. Blood doesn’t pump through the body without the heart and circulatory system.\r\nData moves through your network like blood through veins, delivering vital information to employees who need it to do their jobs. In a business sense, the digital network is the heart and circulatory system. Without a properly functioning network, the entire business collapses. That’s why keeping networks healthy is vitally important. Just as keeping the heart healthy is critical to living a healthy life, a healthy network is a key to a thriving business. It starts with network management.\r\nNetwork management is hardware with a broad range of functions including activities, methods, procedures and the use of tools to administrate, operate, and reliably maintain computer network systems.\r\nStrictly speaking, network Management does not include terminal equipment (PCs, workstations, printers, etc.). Rather, it concerns the reliability, efficiency and capacity/capabilities of data transfer channels.","materialsDescription":" <span style=\"font-weight: bold;\">What Is Network Management?</span>\r\nNetwork management refers to the processes, tools, and applications used to administer, operate and maintain network infrastructure. Performance management and fault analysis also fall into the category of network management. To put it simply, network management is the process of keeping your network healthy, which keeps your business healthy.\r\n<span style=\"font-weight: bold;\">What Are the Components of Network Management?</span>\r\nThe definition of network management is often broad, as network management involves several different components. Here are some of the terms you’ll often hear when network management or network management software is talked about:\r\n<ul><li>Network administration</li><li>Network maintenance</li><li>Network operation</li><li>Network provisioning</li><li>Network security</li></ul>\r\n<span style=\"font-weight: bold;\">Why Is Network Management so Important When It Comes to Network Infrastructure?</span>\r\nThe whole point of network management is to keep the network infrastructure running smoothly and efficiently. Network management helps you:\r\n<ul><li><span style=\"font-style: italic;\">Avoid costly network disruptions.</span> Network downtime can be very costly. In fact, industry research shows the cost can be up to $5,600 per minute or more than $300K per hour. Network disruptions take more than just a financial toll. They also have a negative impact on customer relationships. Slow and unresponsive corporate networks make it harder for employees to serve customers. And customers who feel underserved could be quick to leave.</li><li><span style=\"font-style: italic;\">Improve IT productivity.</span> By monitoring every aspect of the network, an effective network management system does many jobs at once. This frees up IT staff to focus on other things.</li><li><span style=\"font-style: italic;\">Improve network security.</span> With a focus on network management, it’s easy to identify and respond to threats before they propagate and impact end-users. Network management also aims to ensure regulatory and compliance requirements are met.</li><li><span style=\"font-style: italic;\">Gain a holistic view of network performance.</span> Network management gives you a complete view of how your network is performing. It enables you to identify issues and fix them quickly.</li></ul>\r\n<span style=\"font-weight: bold;\">What Are the Challenges of Maintaining Effective Network Management and Network Infrastructure?</span>\r\nNetwork infrastructures can be complex. Because of that complexity, maintaining effective network management is difficult. Advances in technology and the cloud have increased user expectations for faster network speeds and network availability. On top of that, security threats are becoming ever more advanced, varied and numerous. And if you have a large network, it incorporates several devices, systems, and tools that all need to work together seamlessly. As your network scales and your company grows, new potential points of failure are introduced. Increased costs also come into play.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Network_Management_Hardware__1_.png"},{"id":536,"title":"WAN optimization - appliance","alias":"wan-optimization-appliance","description":" WAN optimization appliance is a collection of techniques for increasing data-transfer efficiencies across wide-area networks (WANs). In 2008, the WAN optimization market was estimated to be $1 billion and was to grow to $4.4 billion by 2014 according to Gartner, a technology research firm. In 2015 Gartner estimated the WAN optimization market to be a $1.1 billion market.\r\nThe most common measures of TCP data-transfer efficiencies (i.e., optimization) are throughput, bandwidth requirements, latency, protocol optimization, and congestion, as manifested in dropped packets. In addition, the WAN itself can be classified with regards to the distance between endpoints and the amounts of data transferred. Two common business WAN topologies are Branch to Headquarters and Data Center to Data Center (DC2DC). In general, &quot;Branch&quot; WAN links are closer, use less bandwidth, support more simultaneous connections, support smaller connections and more short-lived connections, and handle a greater variety of protocols. They are used for business applications such as email, content management systems, database application, and Web delivery. In comparison, &quot;DC2DC&quot; WAN links tend to require more bandwidth, are more distant and involve fewer connections, but those connections are bigger (100 Mbit/s to 1 Gbit/s flows) and of longer duration. Traffic on a &quot;DC2DC&quot; WAN may include replication, back up, data migration, virtualization, and other Business Continuity/Disaster Recovery (BC/DR) flow.\r\nWAN optimization has been the subject of extensive academic research almost since the advent of the WAN. In the early 2000s, research in both the private and public sectors turned to improve the end-to-end throughput of TCP, and the target of the first proprietary WAN optimization solutions was the Branch WAN. In recent years, however, the rapid growth of digital data, and the concomitant needs to store and protect it, has presented a need for DC2DC WAN optimization. For example, such optimizations can be performed to increase overall network capacity utilization, meet inter-datacenter transfer deadlines, or minimize average completion times of data transfers. As another example, private inter-datacenter WANs can benefit optimizations for fast and efficient geo-replication of data and content, such as newly computed machine learning models or multimedia content.\r\nComponent techniques of Branch WAN Optimization include deduplication, wide-area file services (WAFS), SMB proxy, HTTPS Proxy, media multicasting, web caching, and bandwidth management. Requirements for DC2DC WAN Optimization also center around deduplication and TCP acceleration, however, these must occur in the context of multi-gigabit data transfer rates. ","materialsDescription":" <span style=\"font-weight: bold;\">What techniques does WAN optimization have?</span>\r\n<ul><li><span style=\"font-weight: bold;\">Deduplication</span> – Eliminates the transfer of redundant data across the WAN by sending references instead of the actual data. By working at the byte level, benefits are achieved across IP applications.</li><li><span style=\"font-weight: bold;\">Compression</span> – Relies on data patterns that can be represented more efficiently. Essentially compression techniques similar to ZIP, RAR, ARJ, etc. are applied on-the-fly to data passing through hardware (or virtual machine) based WAN acceleration appliances.</li><li><span style=\"font-weight: bold;\">Latency optimization</span> – Can include TCP refinements such as window-size scaling, selective acknowledgments, Layer 3 congestion control algorithms, and even co-location strategies in which the application is placed in near proximity to the endpoint to reduce latency. In some implementations, the local WAN optimizer will answer the requests of the client locally instead of forwarding the request to the remote server in order to leverage write-behind and read-ahead mechanisms to reduce WAN latency.</li><li><span style=\"font-weight: bold;\">Caching/proxy</span> – Staging data in local caches; Relies on human behavior, accessing the same data over and over.</li><li><span style=\"font-weight: bold;\">Forward error correction</span> – Mitigates packet loss by adding another loss-recovery packet for every “N” packets that are sent, and this would reduce the need for retransmissions in error-prone and congested WAN links.</li><li><span style=\"font-weight: bold;\">Protocol spoofing</span> – Bundles multiple requests from chatty applications into one. May also include stream-lining protocols such as CIFS.</li><li><span style=\"font-weight: bold;\">Traffic shaping</span> – Controls data flow for specific applications. Giving flexibility to network operators/network admins to decide which applications take precedence over the WAN. A common use case of traffic shaping would be to prevent one protocol or application from hogging or flooding a link over other protocols deemed more important by the business/administrator. Some WAN acceleration devices are able to traffic shape with granularity far beyond traditional network devices. Such as shaping traffic on a per-user AND per application basis simultaneously.</li><li><span style=\"font-weight: bold;\">Equalizing</span> – Makes assumptions on what needs immediate priority based on data usage. Usage examples for equalizing may include wide open unregulated Internet connections and clogged VPN tunnels.</li><li><span style=\"font-weight: bold;\">Connection limits</span> – Prevents access gridlock in and to denial of service or to peer. Best suited for wide-open Internet access links, can also be used links.</li><li><span style=\"font-weight: bold;\">Simple rate limits</span> – Prevents one user from getting more than a fixed amount of data. Best suited as a stop-gap first effort for remediating a congested Internet connection or WAN link.</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_WAN_optimization_appliance.png"},{"id":542,"title":"UTM - Unified Threat Management Appliance","alias":"utm-unified-threat-management-appliance","description":"A unified threat management (UTM) system is a type of network hardware appliance that protects businesses from security threats in a simplified way by combining and integrating multiple security services and features.<br />UTM devices are often packaged as network security appliances that can help protect networks against combined security threats, including malware and attacks that simultaneously target separate parts of the network.\r\nWhile UTM systems and next-generation firewalls (NGFWs) are sometimes comparable, UTM devices include added security features that NGFWs don't offer.\r\nUTM systems provide increased protection and visibility, as well as control over network security, which reduces complexity. UTM systems typically do this via inspection methods that address different types of threats.\r\nThese methods include:\r\n<ul><li>Flow-based inspection, also known as stream-based inspection, samples data that enters a UTM device, and then uses pattern matching to determine whether there is malicious content in the data flow.</li><li>Proxy-based inspection acts as a proxy to reconstruct the content entering a UTM device, and then executes a full inspection of the content to search for potential security threats. If the content is clean, the device sends the content to the user. However, if a virus or other security threat is detected, the device removes the questionable content, and then sends the file or webpage to the user.</li></ul>\r\nUTM devices provide a single platform for multiple network security functions and offer the benefit of a single interface for those security functions, as well as a single point of interface to monitor or analyze security logs for those different functions.<br /><br />","materialsDescription":"<span style=\"font-weight: bold;\">How do UTM Appliances block a computer virus — or many viruses?</span>\r\nUnified threat management appliances have gained traction in the industry due to the emergence of blended threats, which are combinations of different types of malware and attacks that target separate parts of the network simultaneously. Preventing these types of attacks can be difficult when using separate appliances and vendors for each specific security task, as each aspect has to be managed and updated individually in order to remain current in the face of the latest forms of malware and cybercrime. By creating a single point of defense and providing a single console, UTM solutions make dealing with varied threats much easier.\r\nWhile unified threat management solutions do solve some network security issues, they aren't without some drawbacks, with the biggest one being that the single point of defense that an UTM appliance provides also creates a single point of failure. Because of this, many organizations choose to supplement their UTM device with a second software-based perimeter to stop any malware that got through or around the UTM firewall.\r\nWhat kind of companies use a Unified Threat Management system?\r\nUTM was originally for small to medium office businesses to simplify their security systems. But due to its almost universal applicability, it has since become popular with all sectors and larger enterprises. Developments in the technology have allowed it to scale up, opening UTM up to more types of businesses that are looking for a comprehensive gateway security solution.\r\n<span style=\"font-weight: bold;\">What security features does Unified Threat Management have?</span>\r\nAs previously mentioned, most UTM services include a firewall, antivirus and intrusion detection and prevention systems. But they also can include other services that provide additional security.\r\n<ul><li>Data loss prevention software to stop data from exfiltrating the business, which in turn prevents a data leak from occurring.</li><li>Security information and event management software for real-time monitoring of network health, which allows threats and points of weakness to be identified.</li><li>Bandwidth management to regulate and prioritize network traffic, ensuring everything is running smoothly without getting overwhelmed.</li><li>Email filtering to remove spam and dangerous emails before they reach the internal network, lowering the chance of a phishing or similar attack breaching your defenses.</li><li>Web filtering to prevent connections to dangerous or inappropriate sites from a machine on the network. This lowers the chance of infection through malvertising or malicious code on the page. It can also be used to increase productivity within a business, i.e. blocking or restricting social media, gaming sites, etc.</li><li>Application filtering to either a blacklist or whitelist which programs can run, preventing certain applications from communicating in and out of the network, i.e. Facebook messenger.</li></ul>\r\n<span style=\"font-weight: bold;\">What are the benefits of Unified Threat Management?</span>\r\n<ul><li><span style=\"font-weight: bold;\">Simplifies the network</span></li></ul>\r\nBy consolidating multiple security appliances and services into one, you can easily reduce the amount of time spent on maintaining many separate systems that may have become disorganized. This can also improve the performance of the network as there is less bloat. A smaller system also requires less energy and space to run.\r\n<ul><li><span style=\"font-weight: bold;\">Provides greater security and visibility</span></li></ul>\r\nA UTM system can include reporting tools, application filtering and virtual private network (VPN) capabilities, all of which defend your network from more types of threats or improve the existing security. Additionally, monitoring and analysis tools can help locate points of weakness or identify ongoing attacks.\r\n<ul><li><span style=\"font-weight: bold;\">Can defend from more sophisticated attacks</span></li></ul>\r\nBecause UTM defends multiple parts of a network it means that an attack targeting multiple points simultaneously can be repelled more easily. With cyber-attacks getting more sophisticated, having defenses that can match them is of greater importance.\r\nHaving several ways of detecting a threat also means a UTM system is more accurate at identifying potential attacks and preventing them from causing damage.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_UTM_Unified_Threat_Management_Appliance.png"},{"id":544,"title":"DLP - Appliance","alias":"dlp-appliance","description":"DLP (Data Loss Prevention) is a technology for preventing leakage of confidential information from an information system to the outside, as well as technical software and hardware devices for such prevention of leakage. According to most definitions, information leakage is the unauthorized distribution of restricted access data that is not controlled by the owner of this data. This implies that the person who committed the leak has the rights to access information.\r\nThe most effective way to ensure data security on corporate computers today is to use specialized data leakage prevention tools (Data Leak Prevention or DLP). DLP solutions are designed to eliminate the “human factor” and prevent misconduct by preventing (and fixing) data leaks from a computer for as many scripts as possible.\r\nEmail and webmail services, instant messaging services, social networks and forums, cloud file storages, FTP servers - all these benefits of the Internet can at any moment be a channel for leaking corporate information, disclosure of which may be undesirable or even dangerous for business.\r\nYou shouldn’t disregard traditional local channels - data storage devices (flash drives, disks, memory cards), printers and data transfer interfaces and synchronization with smartphones.\r\nAn effective DLP solution should control the widest possible range of network communications channels, local devices, and interfaces. At the same time, the effectiveness of a DLP solution is determined by the flexibility of the settings and the ability to ensure a successful combination of business interests and security.\r\nToday, DLP products are a rapidly growing information security industry, and new products are released very often. Installing a DLP system will allow you to distinguish confidential information from the usual, which in turn will reduce the cost of the entire complex for the protection of information and resources in general. No unimportant moment when choosing a DLP-system is its price, but Data Leak Prevention has a modularity that allows you to protect the channels you need and not pay extra for protecting unnecessary ones.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Loss Prevention (DLP)?</span>\r\nData loss prevention, or DLP, is a set of technologies, products, and techniques that are designed to stop sensitive information from leaving an organization.\r\nData can end up in the wrong hands whether it’s sent through email or instant messaging, website forms, file transfers, or other means. DLP strategies must include solutions that monitor for, detect, and block the unauthorized flow of information.\r\n<span style=\"font-weight: bold;\">How does DLP work?</span>\r\nDLP technologies use rules to look for sensitive information that may be included in electronic communications or to detect abnormal data transfers. The goal is to stop information such as intellectual property, financial data, and employee or customer details from being sent, either accidentally or intentionally, outside the corporate network.\r\n<span style=\"font-weight: bold;\">Why do organizations need DLP solutions?</span>\r\nThe proliferation of business communications has given many more people access to corporate data. Some of these users can be negligent or malicious. The result: a multitude of insider threats that can expose confidential data with a single click. Many government and industry regulations have made DLP a requirement.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_DLP_Appliance.png"},{"id":546,"title":"WAF-web application firewall appliance","alias":"waf-web-application-firewall-appliance","description":"A web application firewall is a special type of application firewall that applies specifically to web applications. It is deployed in front of web applications and analyzes bi-directional web-based (HTTP) traffic - detecting and blocking anything malicious. The OWASP provides a broad technical definition for a WAF as “a security solution on the web application level which - from a technical point of view - does not depend on the application itself.” According to the PCI DSS Information Supplement for requirement 6.6, a WAF is defined as “a security policy enforcement point positioned between a web application and the client endpoint. This functionality can be implemented in hardware, running in an appliance device, or in a typical server running a common operating system. It may be a stand-alone device or integrated into other network components.” In other words, a WAF can be a physical appliance that prevents vulnerabilities in web applications from being exploited by outside threats. These vulnerabilities may be because the application itself is a legacy type or it was insufficiently coded by design. The WAF addresses these code shortcomings by special configurations of rule sets, also known as policies.\r\nPreviously unknown vulnerabilities can be discovered through penetration testing or via a vulnerability scanner. A web application vulnerability scanner, also known as a web application security scanner, is defined in the SAMATE NIST 500-269 as “an automated program that examines web applications for potential security vulnerabilities. In addition to searching for web application-specific vulnerabilities, the tools also look for software coding errors.” Resolving vulnerabilities is commonly referred to as remediation. Corrections to the code can be made in the application but typically a more prompt response is necessary. In these situations, the application of a custom policy for a unique web application vulnerability to provide a temporary but immediate fix (known as a virtual patch) may be necessary.\r\nWAFs are not an ultimate security solution, rather they are meant to be used in conjunction with other network perimeter security solutions such as network firewalls and intrusion prevention systems to provide a holistic defense strategy.\r\nWAFs typically follow a positive security model, a negative security model, or a combination of both as mentioned by the SANS Institute. WAFs use a combination of rule-based logic, parsing, and signatures to detect and prevent attacks such as cross-site scripting and SQL injection. The OWASP produces a list of the top ten web application security flaws. All commercial WAF offerings cover these ten flaws at a minimum. There are non-commercial options as well. As mentioned earlier, the well-known open source WAF engine called ModSecurity is one of these options. A WAF engine alone is insufficient to provide adequate protection, therefore OWASP along with Trustwave's Spiderlabs help organize and maintain a Core-Rule Set via GitHub to use with the ModSecurity WAF engine.","materialsDescription":"A Web Application Firewall or WAF provides security for online services from malicious Internet traffic. WAFs detect and filter out threats such as the OWASP Top 10, which could degrade, compromise or bring down online applications.\r\n<span style=\"font-weight: bold;\">What are Web Application Firewalls?</span>\r\nWeb application firewalls assist load balancing by examining HTTP traffic before it reaches the application server. They also protect against web application vulnerability and unauthorized transfer of data from the web server at a time when security breaches are on the rise. According to the Verizon Data Breach Investigations Report, web application attacks were the most prevalent breaches in 2017 and 2018.\r\nThe PCI Security Standards Council defines a web application firewall as “a security policy enforcement point positioned between a web application and the client endpoint. This functionality can be implemented in software or hardware, running in an appliance device, or in a typical server running a common operating system. It may be a stand-alone device or integrated into other network components.”\r\n<span style=\"font-weight: bold;\">How does a Web Application Firewall wWork?</span>\r\nA web application firewall (WAF) intercepts and inspects all HTTP requests using a security model based on a set of customized policies to weed out bogus traffic. WAFs block bad traffic outright or can challenge a visitor with a CAPTCHA test that humans can pass but a malicious bot or computer program cannot.\r\nWAFs follow rules or policies customized to specific vulnerabilities. As a result, this is how WAFs prevent DDoS attacks. Creating the rules on a traditional WAF can be complex and require expert administration. The Open Web Application Security Project maintains a list of the OWASP top web application security flaws for WAF policies to address.\r\nWAFs come in the form of hardware appliances, server-side software, or filter traffic as-a-service. WAFs can be considered as reverse proxies i.e. the opposite of a proxy server. Proxy servers protect devices from malicious applications, while WAFs protect web applications from malicious endpoints.\r\n<span style=\"font-weight: bold;\">What Are Some Web Application Firewall Benefits?</span>\r\nA web application firewall (WAF) prevents attacks that try to take advantage of the vulnerabilities in web-based applications. The vulnerabilities are common in legacy applications or applications with poor coding or designs. WAFs handle the code deficiencies with custom rules or policies.\r\nIntelligent WAFs provide real-time insights into application traffic, performance, security and threat landscape. This visibility gives administrators the flexibility to respond to the most sophisticated attacks on protected applications.\r\nWhen the Open Web Application Security Project identifies the OWASP top vulnerabilities, WAFs allow administrators to create custom security rules to combat the list of potential attack methods. An intelligent WAF analyzes the security rules matching a particular transaction and provides a real-time view as attack patterns evolve. Based on this intelligence, the WAF can reduce false positives.\r\n<span style=\"font-weight: bold;\">What Is the Difference Between a Firewall and a Web Application Firewall?</span>\r\nA traditional firewall protects the flow of information between servers while a web application firewall is able to filter traffic for a specific web application. Network firewalls and web application firewalls are complementary and can work together.\r\nTraditional security methods include network firewalls, intrusion detection systems (IDS) and intrusion prevention systems (IPS). They are effective at blocking bad L3-L4 traffic at the perimeter on the lower end (L3-L4) of the Open Systems Interconnection (OSI) model. Traditional firewalls cannot detect attacks in web applications because they do not understand Hypertext Transfer Protocol (HTTP) which occurs at layer 7 of the OSI model. They also only allow the port that sends and receives requested web pages from an HTTP server to be open or closed. This is why web application firewalls are effective for preventing attacks like SQL injections, session hijacking and Cross-Site Scripting (XSS).\r\n<span style=\"font-weight: bold;\">When Should You Use a Web Application Firewall?</span>\r\nAny business that uses a website to generate revenue should use a web application firewall to protect business data and services. Organizations that use online vendors should especially deploy web application firewalls because the security of outside groups cannot be controlled or trusted.\r\n<span style=\"font-weight: bold;\">How Do You Use a Web Application Firewall?</span>\r\nA web application firewall requires correct positioning, configuration, administration and monitoring. Web application firewall installation must include the following four steps: secure, monitor, test and improve. This should be a continuous process to ensure application specific protection.<br />The configuration of the firewall should be determined by the business rules and guardrails by the company’s security policy. This approach will allow the rules and filters in the web application firewall to define themselves.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_WAF_web_application_firewall_appliance.png"},{"id":550,"title":"Web filtering - Appliance","alias":"web-filtering-appliance","description":" <span style=\"font-weight: bold; \">A web filter appliance</span> is a device that allows the user to filter all online content for censorship purposes, such that any links, downloads, and email containing offensive materials or pornography is outright blocked or removed. Web filtering appliance can also help you prevent malware infection because, more often than not, malware is usually hidden within links that promise porn or controversial content. Moreover, because the number of online hazards is un stopped increasing every day, it's always prudent to get a web filter appliance that can adapt to the changing times and the ever-evolving hazards posed by the Internet.\r\nAt any rate, content filtering appliance has a distinct advantage over their software counterparts in terms of stable restriction features, unrestricted monitoring, no platform-based limitations, easy upgrades and improvements, and so on. That's because the best web filters are fully integrated software and hardware systems that optimize their hybrid attributes when it comes to content filtering by gaining full, unmitigated control over online usage through well-defined policies as mandated by the owner of the network or the IT security administrator.\r\nGetting a web content filtering appliance that has a list of premium-grade and detailed content analysis with predefined categories (which includes keywords for pornography, game downloads, drugs, violence, adult content, offensive content, racist content, controversial content, and the like) is a must for any major network. All of the items you'll ever need to block should be easily selectable with a click of your mouse as well; after all, sophisticated technology aside, a good web filter appliance should also be intuitive and practical to use as well.<br />&nbsp;","materialsDescription":"<h1 class=\"align-center\">How a Web Content Filter Appliance Works</h1>\r\n<p class=\"align-left\">Typically a web content filter appliance protects Internet users and networks by using a combination of blacklists, URIBL and SURBL filters, category filters and keyword filters. Blacklists, URIBL and SURBL filters work together to prevent users visiting websites known to harbor malware, those that have been identified as fake phishing sites, and those who hid their true identity by using the whois privacy feature or a proxy server. Genuine websites have no reason to hide their true identity.</p>\r\n<p class=\"align-left\">In the category filtering process, the content of millions of webpages are analyzed and assigned a category. System administrators can then choose which categories to block access to (i.e. online shopping, alcohol, pornography, gambling, etc.) depending on whether the web content filter appliance is providing a service to a business, a store, a school, a restaurant, or a workplace. Most appliances for filtering web content also offer the facility to create bespoke categories.</p>\r\n<p class=\"align-left\">Keyword filters have multiple uses. They can be used to block access to websites containing specific words (for example the business name of a competitor), specific file extensions (typically those most commonly used for deploying malware and ransomware), and specific web applications; if, for example, a business wanted to allow its marketing department access to Facebook, but not FaceTime. Effectively, the keyword filters fine-tune the category settings, enhance security and increase productivity.</p>\r\n<h1 class=\"align-center\">Are there any home web filter appliance?</h1>\r\nFor children today, the Internet has always existed. To them, it’s second nature to pop online and watch a funny video, find a fact, or chat with a friend. But, of course, the Internet is also filled with a lot of dark corners (It’s a hop, skip, and a click to adult content). Parents, then, are presented with the daunting task of not only monitoring what sites their children visit but also their screen time consumption. There are a number of home content filtering appliance that allow parents to do just this. The best parental control apps and devices, be they hardware or software, not only put parents in command of such things as the content their children can view and the amount of time they can spend online but help restore a parent’s sense of control. With them, parents, from can restrict access to only specific sites and apps, filter dangerous or explicit web-content, manage time, and even track their location.\r\n\r\n","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Web_filtering_Appliance.png"},{"id":552,"title":"Secure Web Gateway - Appliance","alias":"secure-web-gateway-appliance","description":"Secure web gateways are generally appliance-based security solutions that prevent advanced threats, block unauthorized access to systems or websites, stop malware, and monitor real-time activity across websites accessed by users within the institution.\r\nA secure web gateway is primarily used to monitor and prevent malicious traffic and data from entering, or even leaving, an organization’s network. Typically, it is implemented to secure an organization against threats originating from the Internet, websites and other Web 2.0 products/services. It is generally implemented through a hardware gateway device implemented at the outer boundaries of a network. Some of the features a secure Web gateway provides include URL filtering, application-level control, data leakage prevention, and virus/malware code detection.\r\nA Secure web gateway (SWG) protects users against phishing, malware and other Internet-borne threats. Unlike traditional firewalls, SWGs are focused on layer 7 web traffic inspection, both inbound and outbound. As web security solutions, they apply no protection to WAN traffic, which is left to the corporate next generation firewalls. In recent years, SWGs appeared as a cloud service. The cloud instances enable secure web and cloud access from anywhere – including outside the office by mobile users. The traffic coverage and solution form factor remain the key distinctions between SWGs and next generation firewalls, which often provide a very similar level of security capabilities.\r\nA converged, cloud-based network security solution converges the capabilities of a next generation firewall (WAN and Internet traffic inspection) and the extended coverage for mobile users of SWGs.\r\nA converged approach eliminates the need to maintain policies across multiple point solutions and the appliance life cycle.","materialsDescription":"<span style=\"font-weight: bold;\">Why is a secure web gateway important?</span>\r\nSecure web gateways have become increasingly common as cybercriminals have grown more sophisticated in embedding threat vectors into seemingly innocuous or professional-looking websites. These counterfeit websites can compromise the enterprise as users access them, unleashing malicious code and unauthorized access in the background without the user's knowledge. These fake, criminal websites can be quite convincing.\r\nSome of these scam websites appear to be so authentic that they can convince users to enter credit card numbers and personal identification information (PII) such as social security numbers. Other sites require only the connection to the user to bypass web browser controls and inject malicious code such as viruses or malware into the user's network. Examples include fake online shopping sites posing as brand-name sellers, sites that appear to be legitimate government agencies and even business-to-business intranets. Secure web gateways can also prevent data from flowing out of an organization, making certain that restricted data is blocked from leaving the organization.\r\n<span style=\"font-weight: bold;\">How does a secure web gateway work?</span>\r\nSecure web gateways are installed as a software component or a hardware device on the edge of the network or at user endpoints. All traffic to and from users to other networks must pass through the gateway that monitors it. The gateway monitors this traffic for malicious code, web application use, and all user/non-user attempted URL connections.\r\nThe gateway checks or filters website URL addresses against stored lists of known and approved websites—all others not on the approved lists can be explicitly blocked. Known malicious sites can be explicitly blocked as well. URL filters that maintain allowed web addresses are maintained in whitelists, while known, off-limits sites that are explicitly blocked are maintained in blacklists. In enterprises, these lists are maintained in the secure gateway's database, which then applies the list filters to all incoming and outgoing traffic.\r\nSimilarly, data flowing out of the network can be checked, disallowing restricted data sources—data on the network or user devices that are prohibited from distribution. Application-level controls can also be restricted to known and approved functions, such as blocking uploads to software-as-a-service (SaaS) applications (such as Office 365 and Salesforce.com). Although some enterprises deploy secure web gateways in hardware appliances that filter all incoming and outgoing traffic, many organizations use cloud-based, SaaS secure web gateways as a more flexible and less costly solution to deploy and maintain. Organizations with existing hardware investments often combine the two, using hardware at their larger physical sites and cloud-based gateways for remote locations and traveling workers.\r\n<span style=\"font-weight: bold;\">What are some features of secure web gateways?</span>\r\nBeyond basic URL, web application control and data filtering, secure web gateways should provide additional controls and features that enhance network security.\r\n<ul><li>Encrypted traffic analysis. The gateway should compare all traffic to local and global threat lists and reputation sources first, then also analyze the nature of the traffic itself to determine if any content or code poses a threat to the network. This should include SSL-based encrypted traffic.</li><li>Data Loss Prevention. If, for example, a website accepts uploaded documents or data, the documents should first be scanned for sensitive data before being uploaded.</li><li>Social media protection. All information to and from social media should be scanned and filtered.</li><li>Support for all protocols. HTTP, HTTPS, and FTP internet protocols must be supported. While HTTPS is the industry standard now, many sites still support HTTP and FTP connections.</li><li>Integration with zero-day anti-malware solutions. Threats will be discovered, and integration with anti-malware solutions that can detect zero-day (never seen before) threats deliver the best prevention and remediation.</li><li>Integration with security monitoring. Security administrators should be notified of any web gateway security problems via their monitoring solution of choice, typically a security information and event management (SIEM) solution.</li><li>Choice of location. Choose where your secure web gateway best fits in your network—the edge, at endpoints, or in the cloud.</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Secure_Web_Gateway_Appliance.png"},{"id":556,"title":"Antispam - Appliance","alias":"antispam-appliance","description":"Anti-spam appliances are software or hardware devices integrated with on-board software that implement spam filtering and/or anti-spam for instant messaging (also called &quot;spim&quot;) and are deployed at the gateway or in front of the mail server. They are normally driven by an operating system optimized for spam filtering. They are generally used in larger networks such as companies and corporations, ISPs, universities, etc.\r\nThe reasons hardware anti-spam appliances might be selected instead of software could include:\r\n<ul><li>The customer prefers to buy hardware rather than software</li><li>Ease of installation</li><li>Operating system requirements</li><li>Independence of existing hardware</li></ul>","materialsDescription":"<span style=\"font-weight: bold;\">How does an Antispam Appliance Work?</span>\r\nSince an antispam appliance is hardware, it can be placed at the entry point of the email server to inspect and filter every message that enters the email server. An antispam appliance is capable of evaluating IP addresses that are included in the email messages from the sender. The appliance can also examine the message content and then compare it against the criteria and parameters that have been set for receiving email messages.\r\n<span style=\"font-weight: bold;\">Advantages of an Antispam Appliance</span>\r\nAntispam appliances are capable of providing more email security to large networks because it is hardware that is specifically designed to handle email security on larger networks. Also, since an antispam appliance is hardware, it is much easier to install and configure on a network, as opposed to software that may require a specific operating system infrastructure. For example, if the organization is running the Linux operating system, this type of system will not support antispam filtering software.\r\nAnother advantage of using an antispam appliance is its ability to protect a large network from codes that are designed to destroy the individual computers on the network. These are malicious codes that can enter the email server and then transmit to the email client via spam. When the individual computers get infected, it slows the productivity of the organization and interrupts the network processes.\r\nAlthough many large networks deploy a vulnerability assessment program that can protect the network against criminals with malicious intent, sometimes vulnerability assessment is not enough to protect the massive amounts of email that enter an email server on a large network. This is why it is important to deploy an antispam appliance to provide added security for your email server and the email clients on the individual computers that are connected to the network.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Antispam_Appliance.png"},{"id":562,"title":"DDoS Protection - Appliance","alias":"ddos-protection-appliance","description":"A denial-of-service attack (DoS attack) is a cyber-attack in which the perpetrator seeks to make a machine or network resource unavailable to its intended users by temporarily or indefinitely disrupting services of a host connected to the Internet. Denial of service is typically accomplished by flooding the targeted machine or resource with superfluous requests in an attempt to overload systems and prevent some or all legitimate requests from being fulfilled.\r\nIn a distributed denial-of-service attack (DDoS attack), the incoming traffic flooding the victim originates from many different sources. This effectively makes it impossible to stop the attack simply by blocking a single source.\r\nA DoS or DDoS attack is analogous to a group of people crowding the entry door of a shop, making it hard for legitimate customers to enter, disrupting trade.\r\nCriminal perpetrators of DoS attacks often target sites or services hosted on high-profile web servers such as banks or credit card payment gateways. Revenge, blackmail and activism can motivate these attacks.\r\nBuying a DDoS mitigation appliance can be highly confusing, especially if you have never done this before. While selecting a DDoS protection solution you must understand the right features and have proper background knowledge. In case of distributed denial of service attacks, the bandwidth or resources of any targeted network is flooded with a large amount of malicious traffic. As a result, the system becomes overloaded and crashes. The legitimate users of the network are denied the service. The mail servers, DNS servers and the servers which host high-profile websites are the main target of DDOS attacks. Customers who use services of any shared network are also affected by these attacks. Therefore, anti-DDOS appliances are now vital.","materialsDescription":"<span style=\"font-weight: bold;\">DDoS mitigation solution</span>\r\nThere are two types of DDoS mitigation appliances. These include software and hardware solutions. Identical functions may be claimed by both forms of DDoS protection.\r\n<ul><li>Firewalls are the most common protection appliance, which can deny protocols, IP addresses or ports. However, they are not enough strong to provide protection from the more complicated DDoS attacks.</li><li>Switches are also effective solutions for preventing DDoS attacks. Most of these switches possess rate limiting capability and ACL. Some switches provide packet inspection, traffic shaping, delayed binding and rate limiting. They can detect the fake traffic through balancing and rate filtering.</li><li>Like switches, routers also have rate limiting and ACL capability. Most routers are capable of moving under DoS attacks.</li><li>Intrusion prevention systems are another option for you when it comes to protection from DDoS attacks. This solution can be effective in several cases of DDoS attacks. It can identify DDoS attacks and stop them because they possess the granularity as well as processing power required for identifying the attacks. Then they work in an automated manner to resolve the situation.</li><li>There are also rate-based intrusion prevention mechanisms, which are capable of analyzing traffic granularity. This system can also monitor the pattern of traffic.</li></ul>\r\nYou must check the connectivity while selecting a DDoS mitigation appliance. Capacity is also an important aspect of a DDoS protection solutions. You must figure out the number of ports, IPs, protocols, hosts, URLs and user agents that can be monitored by the appliance. An effective DDoS mitigation solution must also be properly customizable. Your DDoS mitigation appliance should be such that it can be upgraded according to your requirements. These are some important factors that you need to consider while choosing a DDoS mitigation appliance for your system.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_DDoS_Protection_Appliance.png"},{"id":784,"title":"NGFW - next-generation firewall - Appliance","alias":"ngfw-next-generation-firewall-appliance","description":" A next-generation firewall (NGFW) is a part of the third generation of firewall technology, combining a traditional firewall with other network device filtering functionalities, such as an application firewall using in-line deep packet inspection (DPI), an intrusion prevention system (IPS). Other techniques might also be employed, such as TLS/SSL encrypted traffic inspection, website filtering, QoS/bandwidth management, antivirus inspection and third-party identity management integration (i.e. LDAP, RADIUS, Active Directory).\r\nNGFWs include the typical functions of traditional firewalls such as packet filtering, network- and port-address translation (NAT), stateful inspection, and virtual private network (VPN) support. The goal of next-generation firewalls is to include more layers of the OSI model, improving filtering of network traffic that is dependent on the packet contents.\r\nNGFWs perform deeper inspection compared to stateful inspection performed by the first- and second-generation firewalls. NGFWs use a more thorough inspection style, checking packet payloads and matching signatures for harmful activities such as exploitable attacks and malware.\r\nImproved detection of encrypted applications and intrusion prevention service. Modern threats like web-based malware attacks, targeted attacks, application-layer attacks, and more have had a significantly negative effect on the threat landscape. In fact, more than 80% of all new malware and intrusion attempts are exploiting weaknesses in applications, as opposed to weaknesses in networking components and services.\r\nStateful firewalls with simple packet filtering capabilities were efficient blocking unwanted applications as most applications met the port-protocol expectations. Administrators could promptly prevent an unsafe application from being accessed by users by blocking the associated ports and protocols. But today, blocking a web application like Farmville that uses port 80 by closing the port would also mean complications with the entire HTTP protocol.\r\nProtection based on ports, protocols, IP addresses is no more reliable and viable. This has led to the development of identity-based security approach, which takes organizations a step ahead of conventional security appliances which bind security to IP-addresses.\r\nNGFWs offer administrators a deeper awareness of and control over individual applications, along with deeper inspection capabilities by the firewall. Administrators can create very granular &quot;allow/deny&quot; rules for controlling use of websites and applications in the network. ","materialsDescription":"<span style=\"font-weight: bold;\"> What is a next-generation firewall (NGFW)?</span>\r\nAn NGFW contains all the normal defences that a traditional firewall has as well as a type of intrusion prevention software and application control, alongside other bonus security features. NGFWs are also capable of deep packet inspection which enables more robust filters.\r\nIntrusion prevention software monitors network activity to detect and stop vulnerability exploits from occurring. This is usually done by monitoring for breaches against the network policies in place as a breach is usually indicative of malicious activity.\r\nApplication control software simply sets up a hard filter for programs that are trying to send or receive data over the Internet. This can either be done by blacklist (programs in the filter are blocked) or by whitelist (programs not in the filter are blocked).","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_NGFW.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3348,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/_xdair-300.png","logo":true,"scheme":false,"title":"Tresys XD Air","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"tresys-xd-air","companyTitle":"Tresys","companyTypes":["supplier","vendor"],"companyId":5159,"companyAlias":"tresys","description":"&nbsp;XD Air is an integrated hardware/software package that inspects and cleans files on portable media of malware and other malicious content. A laptop-based kiosk, XD Air was developed in conjunction with the National Security Agency as a file sanitization tool to enable the safe use of portable media. In the six years since its development, more than 1,000 XD Air systems have been successfully deployed in government, nuclear, and commercial environments.<br /><br /><span style=\"font-weight: bold;\">Application Flexibility</span>\r\nProven in a variety of government and critical infrastructure applications, XD Air:\r\n<ul><li>Protects against media-borne and data-borne threats when transferring data to secure or critical networks.</li></ul>\r\n<ul><li>Enables assured transfer of classified data between high-risk networks using portable media (meets the requirements of JTF-GNO CTO-10-004A for Removable Flash Media Device Implementation).</li></ul>\r\n<ul><li>Assists in publishing digital documents by exposing hidden content and verifying cleansing before release—helping ensure that classified or confidential data is not inadvertently disseminated.</li></ul>\r\n<ul><li>Verifies the authenticity of content from trusted sources.</li></ul>\r\n<br /><span style=\"font-weight: bold;\">How It Works</span>\r\n\r\n<ul><li>Inspects and cleans files on removable media to mitigate the risk of introducing malicious content</li></ul>\r\n<ul><li>Offers three methods of protection: Known Good, Known Bad and Known Source</li></ul>\r\n<ul><li>Applies advanced filtering techniques to perform deep content inspection of complex file types, exposing hidden threats and data missed by conventional antivirus and anti-malware protection</li></ul>\r\n<ul><li>XD Air is hardened against attacks from media-borne malware</li></ul>\r\n<ul><li>Securely erases media</li></ul>","shortDescription":"XD Air™ is the only U.S. Cyber Command-approved tool for the transfer of classified data using portable media.\r\n","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":14,"sellingCount":17,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Tresys XD Air","keywords":"","description":"&nbsp;XD Air is an integrated hardware/software package that inspects and cleans files on portable media of malware and other malicious content. A laptop-based kiosk, XD Air was developed in conjunction with the National Security Agency as a file sanitization ","og:title":"Tresys XD Air","og:description":"&nbsp;XD Air is an integrated hardware/software package that inspects and cleans files on portable media of malware and other malicious content. A laptop-based kiosk, XD Air was developed in conjunction with the National Security Agency as a file sanitization ","og:image":"https://old.roi4cio.com/fileadmin/user_upload/_xdair-300.png"},"eventUrl":"","translationId":3349,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":560,"title":"IPC - Information Protection and Control - Appliance","alias":"ipc-information-protection-and-control-appliance","description":" Information Protection and Control (IPC) is a technology for protecting confidential information from internal threats. IPC class hardware solutions are designed to protect information from internal threats, prevent various types of information leaks, corporate espionage, and business intelligence. The term IPC combines two main technologies: encryption of storage media at all points of the network and control of technical channels of information leakage using Data Loss Prevention (DLP) technologies. Network, application and data access control is a possible third technology in IPC class systems. IPC includes solutions of the Data Loss Prevention (DLP) class, a system for encrypting corporate information and controlling access to it. The term IPC was one of the first to use IDC analyst Brian Burke in his report, Information Protection and Control Survey: Data Loss Prevention and Encryption Trends.\r\nIPC technology is a logical continuation of DLP technology and allows you to protect data not only from leaks through technical channels, that is, insiders, but also from unauthorized user access to the network, information, applications, and in cases where the direct storage medium falls into the hands of third parties. This allows you to prevent leaks in those cases when an insider or a person who does not have legal access to data gain access to the direct carrier of information.\r\nThe main objective of IPC systems is to prevent the transfer of confidential information outside the corporate information system. Such a transfer (leak) may be intentional or unintentional. Practice shows that most of the leaks (more than 75%) do not occur due to malicious intent, but because of errors, carelessness, carelessness, and negligence of employees - it is much easier to detect such cases. The rest is connected with the malicious intent of operators and users of enterprise information systems, in particular, industrial espionage and competitive intelligence. Obviously, malicious insiders, as a rule, try to trick IPC analyzers and other control systems.","materialsDescription":" <span style=\"font-weight: bold;\">What is Information Protection and Control (IPC)?</span>\r\nIPC (English Information Protection and Control) is a generic name for technology to protect confidential information from internal threats.\r\nIPC apparel solutions are designed to prevent various types of information leaks, corporate espionage, and business intelligence. IPC combines two main technologies: media encryption and control of technical channels of information leakage (Data Loss Prevention - DLP). Also, the functionality of IPC systems may include systems of protection against unauthorized access (unauthorized access).\r\n<span style=\"font-weight: bold;\">What are the objectives of IPC class systems?</span>\r\n<ul><li>preventing the transfer of confidential information beyond the corporate information system;</li><li>prevention of outside transmission of not only confidential but also other undesirable information (offensive expressions, spam, eroticism, excessive amounts of data, etc.);</li><li>preventing the transmission of unwanted information not only from inside to outside but also from outside to inside the organization’s information system;</li><li>preventing employees from using the Internet and network resources for personal purposes;</li><li>spam protection;</li><li>virus protection;</li><li>optimization of channel loading, reduction of inappropriate traffic;</li><li>accounting of working hours and presence at the workplace;</li><li>tracking the reliability of employees, their political views, beliefs, collecting dirt;</li><li>archiving information in case of accidental deletion or damage to the original;</li><li>protection against accidental or intentional violation of internal standards;</li><li>ensuring compliance with standards in the field of information security and current legislation.</li></ul>\r\n<span style=\"font-weight: bold;\">Why is DLP technology used in IPC?</span>\r\nIPC DLP technology supports monitoring of the following technical channels for confidential information leakage:\r\n<ul><li>corporate email;</li><li>webmail;</li><li>social networks and blogs;</li><li>file-sharing networks;</li><li>forums and other Internet resources, including those made using AJAX technology;</li><li>instant messaging tools (ICQ, Mail.Ru Agent, Skype, AOL AIM, Google Talk, Yahoo Messenger, MSN Messenger, etc.);</li><li>P2P clients;</li><li>peripheral devices (USB, LPT, COM, WiFi, Bluetooth, etc.);</li><li>local and network printers.</li></ul>\r\nDLP technologies in IPC support control, including the following communication protocols:\r\n<ul><li>FTP;</li><li>FTP over HTTP;</li><li>FTPS;</li><li>HTTP;</li><li>HTTPS (SSL);</li><li>NNTP;</li><li>POP3;</li><li>SMTP.</li></ul>\r\n<span style=\"font-weight: bold;\">What information protection facilities does IPC technology include?</span>\r\nIPC technology includes the ability to encrypt information at all key points in the network. The objects of information security are:\r\n<ul><li>Server hard drives;</li><li>SAN;</li><li>NAS;</li><li>Magnetic tapes;</li><li>CD/DVD/Blue-ray discs;</li><li>Personal computers (including laptops);</li><li>External devices.</li></ul>\r\nIPC technologies use various plug-in cryptographic modules, including the most efficient algorithms DES, Triple DES, RC5, RC6, AES, XTS-AES. The most used algorithms in IPC solutions are RC5 and AES, the effectiveness of which can be tested on the project [distributed.net]. They are most effective for solving the problems of encrypting data of large amounts of data on server storages and backups.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_IPC_Information_Protection_and_Control_Appliance.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3350,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/VIT-400-0000.jpg","logo":true,"scheme":false,"title":"WizLAN VIT-400 Cyber Network Security","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"wizlan-vit-400-cyber-network-security","companyTitle":"WizLAN","companyTypes":["supplier","vendor"],"companyId":5241,"companyAlias":"wizlan","description":"The VIT-400 is a Fast Ethernet single-direction network to network fibeoptic coupled isolation device - Network to Network Diode, desigen and approved for Critical Infrastructure Protection (CIP) connectivity.<br /><br />Composed of a pair of single-direction network diodes (VIT-42TX/RX like), internally connected by a single fiber optic cable and having two separated power supplies, the VIT-400 provides complet protection, isolation and security for unidirectional transparent data transfer between two networks.<br /><br />Separating between the pure HW network to network diode and the unidirectional VectorIT SW application, installed on the networks endpoint servers, assures unbreakable single-direction solution for protecting the networks against intrusion and leakage.<br /><br />VectorIT software application facilitates unidirectional transfer of certain TCP-based protocols as well as raw files over standard Ethernet interfaces with utilization of up-to full wire speed. <br />Currently supported protocols are FTP, SMTP TCP and raw files. The software is dedicated to and employs only unidirectional data flow over single or bidirectional link, but has otherwise no relation to data security services.<br /><br />The VIT-400 includes a uniqe link verification function in which the link of the incoming endpoint (receiving server) will drop if there is any problem with the end to end link continuity up-to the outgoing endpopint (transmitting server). This is a powerfull HW management feature aspecially for single direction applications.","shortDescription":"WizLAN VIT-400 Cyber Network Security is a Fast Ethernet single-direction network to network fibeoptic coupled isolation device - Network to Network Diode.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":0,"sellingCount":20,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"WizLAN VIT-400 Cyber Network Security","keywords":"","description":"The VIT-400 is a Fast Ethernet single-direction network to network fibeoptic coupled isolation device - Network to Network Diode, desigen and approved for Critical Infrastructure Protection (CIP) connectivity.<br /><br />Composed of a pair of single-direction ","og:title":"WizLAN VIT-400 Cyber Network Security","og:description":"The VIT-400 is a Fast Ethernet single-direction network to network fibeoptic coupled isolation device - Network to Network Diode, desigen and approved for Critical Infrastructure Protection (CIP) connectivity.<br /><br />Composed of a pair of single-direction ","og:image":"https://old.roi4cio.com/fileadmin/user_upload/VIT-400-0000.jpg"},"eventUrl":"","translationId":3351,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":513,"title":"Networking","alias":"networking","description":" Networking hardware, also known as network equipment or computer networking devices, are electronic devices which are required for communication and interaction between devices on a computer network. Specifically, they mediate data transmission in a computer network. Units which are the last receiver or generate data are called hosts or data terminal equipment.\r\nNetworking devices may include gateways, routers, network bridges, modems, wireless access points, networking cables, line drivers, switches, hubs, and repeaters; and may also include hybrid network devices such as multilayer switches, protocol converters, bridge routers, proxy servers, firewalls, network address translators, multiplexers, network interface controllers, wireless network interface controllers, ISDN terminal adapters and other related hardware.\r\nThe most common kind of networking hardware today is a copper-based Ethernet adapter which is a standard inclusion on most modern computer systems. Wireless networking has become increasingly popular, especially for portable and handheld devices.\r\nOther networking hardware used in computers includes data center equipment (such as file servers, database servers and storage areas), network services (such as DNS, DHCP, email, etc.) as well as devices which assure content delivery.\r\nTaking a wider view, mobile phones, tablet computers and devices associated with the internet of things may also be considered networking hardware. As technology advances and IP-based networks are integrated into building infrastructure and household utilities, network hardware will become an ambiguous term owing to the vastly increasing number of network capable endpoints.","materialsDescription":" <span style=\"font-weight: bold;\">What is network equipment?</span>\r\nNetwork equipment - devices necessary for the operation of a computer network, for example: a router, switch, hub, patch panel, etc. You can distinguish between active and passive network equipment.\r\n<span style=\"font-weight: bold;\">What is an active network equipment?</span>\r\nActive networking equipment is equipment followed by some “smart” feature. That is, a router, switch (switch), etc. are active network equipment.\r\n<span style=\"font-weight: bold;\">What is passive network equipment?</span>\r\nPassive network equipment - equipment not endowed with &quot;intellectual&quot; features. For example - cable system: cable (coaxial and twisted pair (UTP/STP)), plug / socket (RG58, RJ45, RJ11, GG45), repeater (repeater), patch panel, hub (hub), balun (balun) for coaxial cables (RG-58), etc. Also, passive equipment can include mounting cabinets and racks, telecommunication cabinets.\r\n<span style=\"font-weight: bold;\">What are the main network components?</span>\r\nThe main components of the network are workstations, servers, transmission media (cables) and network equipment.\r\n<span style=\"font-weight: bold;\">What are workstations?</span>\r\nWorkstations are network computers where network users implement application tasks.\r\n<span style=\"font-weight: bold;\">What are network servers?</span>\r\nNetwork servers - hardware and software systems that perform the functions of controlling the distribution of network shared resources. A server can be any computer connected to the network on which the resources used by other devices on the local network are located. As the server hardware, fairly powerful computers are used.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Networking.png"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":548,"title":"Web security - Appliance","alias":"web-security-appliance","description":"A security appliance is any form of server appliance that is designed to protect computer networks from unwanted traffic. Types of network security appliance:\r\n<span style=\"font-weight: bold;\">Active devices</span> block unwanted traffic. Examples of such devices are firewalls, anti-virus scanning devices, and content filtering devices. For instance, if you want to make sure that you do not get pointless spam and other unnecessary issues, installing an active device might be a great idea. Active devices include anti-virus scanning devices, which will automatically scan throughout the network to ensure that no virus exists within the protected network. Then, there are web filtering appliances as well as firewalls, the purpose of both of which is to ensure that only useful content and traffic flows through the network and all pointless or harmful data is filtered.\r\n<span style=\"font-weight: bold;\">Passive devices detect and report on unwanted traffic.</span> A common example is intrusion detection appliances, which are installed in order to determine whether the network has been compromised in any way. These devices usually work in the background at all times.\r\n<span style=\"font-weight: bold;\">Preventative devices</span> scan networks and identify potential security problems (such as penetration testing and vulnerability assessment appliances). These devices are usually designed to 'prevent' damage to the network by identifying problems in advance. Common examples include devices that employ penetration testing as well as those devices which carry out vulnerability assessment on networks.\r\n<span style=\"font-weight: bold;\">Unified Threat Management (UTM)</span> combines features together into one system, such as some firewalls, content filtering, web caching etc. UTM devices are designed to provide users with a one-stop solution to all of their network needs and internet security appliances. As the name clearly suggests, these devices provide the features of all of the other network devices and condense them into one. These devices are designed to provide a number of different network security options in one package, hence providing networks with a simple solution. Rather than installing four different devices, users can easily install one and be done with it. The market of UTM devices has exceeded the billion dollar mark already, which just goes to show how popular these devices have become amongst network users.\r\nOne of the most popular and accessible types of web security appliance tools is the hardware <span style=\"font-weight: bold;\">keylogger.</span> This device is placed covertly between the case and keyboard with an output for the computer case and input for the keyboard. As hardware standards have changed over time, a USB hardware keylogger provides access on many devices.\r\nThe <span style=\"font-weight: bold;\">web proxy appliance</span> is basically hardware you use to manage user web access. More to the point, it's the type of device that handles the blocking or controlling of suspicious programs. It's typically placed in between network users and the worldwide web; ergo, it's most popular application is serving as a central control hub over employee Internet use by corporations and enterprises. It's the in-between gateway that serves as a termination point of sorts for online communications within a network and is capable of applying a multitude of rule-based limitations on Internet traffic, web content, and requests before they even end up with end users.\r\nAnother commonly used hardware tool is the <span style=\"font-weight: bold;\">wireless antenna.</span> These can be used to surveil a wide variety of wireless communications, including local cellular and internet service networks. More mechanical and general devices may include lockpicks or portable probes and hijack chips for compromising electronic devices through the physical circuit.\r\n<span style=\"font-weight: bold;\">Secure web gateway appliances</span> are solutions to prevent advanced threats, block unauthorized access to systems or websites, stop malware, and monitor real-time activity across websites accessed by users within the institution. Software and cloud-based platforms now perform this function as well.","materialsDescription":"<h1 class=\"align-center\"> What are the top Network Security Appliance brands?</h1>\r\n<span style=\"font-weight: bold;\">Blue Coat Systems,</span> Sunnyvale, Calif.-based Blue Coat has been part of security powerhouse Symantec since 2016.\r\n<span style=\"font-weight: bold;\">F5 Networks,</span> the Seattle-based network application delivery vendor, sold about $17.6 million in network security appliances through the channel in the second quarter, NPD said.\r\n<span style=\"font-weight: bold;\">SonicWall.</span>Firewall power player SonicWall sold about $23.5 million in network security appliances through the channel in the second quarter, according to NPD.\r\n<span style=\"font-weight: bold;\">Fortinet,</span> Sunnyvale, Calif., security software vendor Fortinet sold about $24.4 million in network security appliances through the channel in the second quarter, NPD said.\r\n<span style=\"font-weight: bold;\">Cisco Systems,</span> Cisco Systems was the quarter's growth champion, posting $77.2 million in network security appliance sales through the channel in the period, beating the previous year’s quarterly total of $62.3 million by about 24 percent, according to NPD.\r\n<span style=\"font-weight: bold;\">Palo Alto Networks.</span> With $94.2 million in network security appliance sales in the quarter, Palo Alto Networks was the best-selling network security appliance brand of the second quarter, according to NPD.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Web_security_Appliance.png"},{"id":560,"title":"IPC - Information Protection and Control - Appliance","alias":"ipc-information-protection-and-control-appliance","description":" Information Protection and Control (IPC) is a technology for protecting confidential information from internal threats. IPC class hardware solutions are designed to protect information from internal threats, prevent various types of information leaks, corporate espionage, and business intelligence. The term IPC combines two main technologies: encryption of storage media at all points of the network and control of technical channels of information leakage using Data Loss Prevention (DLP) technologies. Network, application and data access control is a possible third technology in IPC class systems. IPC includes solutions of the Data Loss Prevention (DLP) class, a system for encrypting corporate information and controlling access to it. The term IPC was one of the first to use IDC analyst Brian Burke in his report, Information Protection and Control Survey: Data Loss Prevention and Encryption Trends.\r\nIPC technology is a logical continuation of DLP technology and allows you to protect data not only from leaks through technical channels, that is, insiders, but also from unauthorized user access to the network, information, applications, and in cases where the direct storage medium falls into the hands of third parties. This allows you to prevent leaks in those cases when an insider or a person who does not have legal access to data gain access to the direct carrier of information.\r\nThe main objective of IPC systems is to prevent the transfer of confidential information outside the corporate information system. Such a transfer (leak) may be intentional or unintentional. Practice shows that most of the leaks (more than 75%) do not occur due to malicious intent, but because of errors, carelessness, carelessness, and negligence of employees - it is much easier to detect such cases. The rest is connected with the malicious intent of operators and users of enterprise information systems, in particular, industrial espionage and competitive intelligence. Obviously, malicious insiders, as a rule, try to trick IPC analyzers and other control systems.","materialsDescription":" <span style=\"font-weight: bold;\">What is Information Protection and Control (IPC)?</span>\r\nIPC (English Information Protection and Control) is a generic name for technology to protect confidential information from internal threats.\r\nIPC apparel solutions are designed to prevent various types of information leaks, corporate espionage, and business intelligence. IPC combines two main technologies: media encryption and control of technical channels of information leakage (Data Loss Prevention - DLP). Also, the functionality of IPC systems may include systems of protection against unauthorized access (unauthorized access).\r\n<span style=\"font-weight: bold;\">What are the objectives of IPC class systems?</span>\r\n<ul><li>preventing the transfer of confidential information beyond the corporate information system;</li><li>prevention of outside transmission of not only confidential but also other undesirable information (offensive expressions, spam, eroticism, excessive amounts of data, etc.);</li><li>preventing the transmission of unwanted information not only from inside to outside but also from outside to inside the organization’s information system;</li><li>preventing employees from using the Internet and network resources for personal purposes;</li><li>spam protection;</li><li>virus protection;</li><li>optimization of channel loading, reduction of inappropriate traffic;</li><li>accounting of working hours and presence at the workplace;</li><li>tracking the reliability of employees, their political views, beliefs, collecting dirt;</li><li>archiving information in case of accidental deletion or damage to the original;</li><li>protection against accidental or intentional violation of internal standards;</li><li>ensuring compliance with standards in the field of information security and current legislation.</li></ul>\r\n<span style=\"font-weight: bold;\">Why is DLP technology used in IPC?</span>\r\nIPC DLP technology supports monitoring of the following technical channels for confidential information leakage:\r\n<ul><li>corporate email;</li><li>webmail;</li><li>social networks and blogs;</li><li>file-sharing networks;</li><li>forums and other Internet resources, including those made using AJAX technology;</li><li>instant messaging tools (ICQ, Mail.Ru Agent, Skype, AOL AIM, Google Talk, Yahoo Messenger, MSN Messenger, etc.);</li><li>P2P clients;</li><li>peripheral devices (USB, LPT, COM, WiFi, Bluetooth, etc.);</li><li>local and network printers.</li></ul>\r\nDLP technologies in IPC support control, including the following communication protocols:\r\n<ul><li>FTP;</li><li>FTP over HTTP;</li><li>FTPS;</li><li>HTTP;</li><li>HTTPS (SSL);</li><li>NNTP;</li><li>POP3;</li><li>SMTP.</li></ul>\r\n<span style=\"font-weight: bold;\">What information protection facilities does IPC technology include?</span>\r\nIPC technology includes the ability to encrypt information at all key points in the network. The objects of information security are:\r\n<ul><li>Server hard drives;</li><li>SAN;</li><li>NAS;</li><li>Magnetic tapes;</li><li>CD/DVD/Blue-ray discs;</li><li>Personal computers (including laptops);</li><li>External devices.</li></ul>\r\nIPC technologies use various plug-in cryptographic modules, including the most efficient algorithms DES, Triple DES, RC5, RC6, AES, XTS-AES. The most used algorithms in IPC solutions are RC5 and AES, the effectiveness of which can be tested on the project [distributed.net]. They are most effective for solving the problems of encrypting data of large amounts of data on server storages and backups.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_IPC_Information_Protection_and_Control_Appliance.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3368,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/VADO450.jpg","logo":true,"scheme":false,"title":"VADO One Way Data Diode","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"vado-one-way-data-diode","companyTitle":"VADO Security Technologies","companyTypes":["supplier","vendor"],"companyId":5250,"companyAlias":"vado-security-technologies","description":"<span style=\"color: rgb(97, 97, 97); \">VADO Security develops and markets Network Data Diodes for national governments, Gas &amp; Oil Industries, Banking and more, guarding against cyber attacks.<br /></span>\r\n<span style=\"color: rgb(97, 97, 97); \">Vado is a manufacturer of data diode systems. The Vado diode is composed of hardware &amp; software (called &quot;agents&quot;). The hardware diode is composed of a TX hardware unit and an RX hardware unit. The units are connected to servers on each side via ethernet cables and connected to each other (TX to RX) via a single fiber optic cable.</span>\r\n<span style=\"color: rgb(97, 97, 97); \">The VADO One Way Data Diode appliance is designed to allow unidirectional data transfer to networks that must be physically detached for security reasons, such as R&amp;D and production systems in the defense industry.</span>\r\n\r\n\r\n<span style=\"font-weight: bold;\">The main features of VADO One Way Data Diode:</span>\r\n<ul><li>Proven Technology</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">100% hack proof Technology for all 100 Mb &amp; 1G systems\r\n<ul><li>Log Management</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">System Action Logs &amp; File transfer logs.<br />Sent via Email, Syslog or File\r\n<ul><li>User Interface</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Central &amp; Intuitive User Interface \r\n<ul><li>Data Transfer Reliability</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Reliability of Data transfer with unique ERD system\r\n<ul><li>Virtual Machine Support</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">OS Virtual Machine Support for all Software Agents (No Change at Hardware Level)\r\n<ul><li>Windows OS Support</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Works with all Windows OS (32,64), Server or PC &amp; VM (Patent Pending)\r\n<ul><li>High Availability</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">High Availability for all Data Diode Agents &amp; Hardware\r\n<ul><li>Pre &amp; Post Send Scripts Option</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Ability to Activate Scripts on Files Pre/Post Send/Receive Per Channel\r\n<ul><li>Multi-Agents</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Ability to use Multi-Agents on One Server <br />With One Hardware System\r\n<ul><li>No File Size Limits</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Transfer any File Size or Type\r\n<ul><li>XML Filtering</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Built in XML Schema Filtering\r\n<ul><li>Files Filter</li></ul>\r\n<div class=\"indent\"><div class=\"indent\">Filter Files by Type or Size","shortDescription":"The VADO One Way Data Diode appliance is designed to allow unidirectional data transfer to networks","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":13,"sellingCount":17,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"VADO One Way Data Diode","keywords":"","description":"<span style=\"color: rgb(97, 97, 97); \">VADO Security develops and markets Network Data Diodes for national governments, Gas &amp; Oil Industries, Banking and more, guarding against cyber attacks.<br /></span>\r\n<span style=\"color: rgb(97, 97, 97); \">Vado is a m","og:title":"VADO One Way Data Diode","og:description":"<span style=\"color: rgb(97, 97, 97); \">VADO Security develops and markets Network Data Diodes for national governments, Gas &amp; Oil Industries, Banking and more, guarding against cyber attacks.<br /></span>\r\n<span style=\"color: rgb(97, 97, 97); \">Vado is a m","og:image":"https://old.roi4cio.com/fileadmin/user_upload/VADO450.jpg"},"eventUrl":"","translationId":3369,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":548,"title":"Web security - Appliance","alias":"web-security-appliance","description":"A security appliance is any form of server appliance that is designed to protect computer networks from unwanted traffic. Types of network security appliance:\r\n<span style=\"font-weight: bold;\">Active devices</span> block unwanted traffic. Examples of such devices are firewalls, anti-virus scanning devices, and content filtering devices. For instance, if you want to make sure that you do not get pointless spam and other unnecessary issues, installing an active device might be a great idea. Active devices include anti-virus scanning devices, which will automatically scan throughout the network to ensure that no virus exists within the protected network. Then, there are web filtering appliances as well as firewalls, the purpose of both of which is to ensure that only useful content and traffic flows through the network and all pointless or harmful data is filtered.\r\n<span style=\"font-weight: bold;\">Passive devices detect and report on unwanted traffic.</span> A common example is intrusion detection appliances, which are installed in order to determine whether the network has been compromised in any way. These devices usually work in the background at all times.\r\n<span style=\"font-weight: bold;\">Preventative devices</span> scan networks and identify potential security problems (such as penetration testing and vulnerability assessment appliances). These devices are usually designed to 'prevent' damage to the network by identifying problems in advance. Common examples include devices that employ penetration testing as well as those devices which carry out vulnerability assessment on networks.\r\n<span style=\"font-weight: bold;\">Unified Threat Management (UTM)</span> combines features together into one system, such as some firewalls, content filtering, web caching etc. UTM devices are designed to provide users with a one-stop solution to all of their network needs and internet security appliances. As the name clearly suggests, these devices provide the features of all of the other network devices and condense them into one. These devices are designed to provide a number of different network security options in one package, hence providing networks with a simple solution. Rather than installing four different devices, users can easily install one and be done with it. The market of UTM devices has exceeded the billion dollar mark already, which just goes to show how popular these devices have become amongst network users.\r\nOne of the most popular and accessible types of web security appliance tools is the hardware <span style=\"font-weight: bold;\">keylogger.</span> This device is placed covertly between the case and keyboard with an output for the computer case and input for the keyboard. As hardware standards have changed over time, a USB hardware keylogger provides access on many devices.\r\nThe <span style=\"font-weight: bold;\">web proxy appliance</span> is basically hardware you use to manage user web access. More to the point, it's the type of device that handles the blocking or controlling of suspicious programs. It's typically placed in between network users and the worldwide web; ergo, it's most popular application is serving as a central control hub over employee Internet use by corporations and enterprises. It's the in-between gateway that serves as a termination point of sorts for online communications within a network and is capable of applying a multitude of rule-based limitations on Internet traffic, web content, and requests before they even end up with end users.\r\nAnother commonly used hardware tool is the <span style=\"font-weight: bold;\">wireless antenna.</span> These can be used to surveil a wide variety of wireless communications, including local cellular and internet service networks. More mechanical and general devices may include lockpicks or portable probes and hijack chips for compromising electronic devices through the physical circuit.\r\n<span style=\"font-weight: bold;\">Secure web gateway appliances</span> are solutions to prevent advanced threats, block unauthorized access to systems or websites, stop malware, and monitor real-time activity across websites accessed by users within the institution. Software and cloud-based platforms now perform this function as well.","materialsDescription":"<h1 class=\"align-center\"> What are the top Network Security Appliance brands?</h1>\r\n<span style=\"font-weight: bold;\">Blue Coat Systems,</span> Sunnyvale, Calif.-based Blue Coat has been part of security powerhouse Symantec since 2016.\r\n<span style=\"font-weight: bold;\">F5 Networks,</span> the Seattle-based network application delivery vendor, sold about $17.6 million in network security appliances through the channel in the second quarter, NPD said.\r\n<span style=\"font-weight: bold;\">SonicWall.</span>Firewall power player SonicWall sold about $23.5 million in network security appliances through the channel in the second quarter, according to NPD.\r\n<span style=\"font-weight: bold;\">Fortinet,</span> Sunnyvale, Calif., security software vendor Fortinet sold about $24.4 million in network security appliances through the channel in the second quarter, NPD said.\r\n<span style=\"font-weight: bold;\">Cisco Systems,</span> Cisco Systems was the quarter's growth champion, posting $77.2 million in network security appliance sales through the channel in the period, beating the previous year’s quarterly total of $62.3 million by about 24 percent, according to NPD.\r\n<span style=\"font-weight: bold;\">Palo Alto Networks.</span> With $94.2 million in network security appliance sales in the quarter, Palo Alto Networks was the best-selling network security appliance brand of the second quarter, according to NPD.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Web_security_Appliance.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4904,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/NXP_Semiconductors_IoT_GATEWAY_Solution.png","logo":true,"scheme":false,"title":"NXP Semiconductors IoT Gateway Solution","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"nxp-semiconductors-iot-gateway-solution","companyTitle":"NXP Semiconductors","companyTypes":["supplier"],"companyId":5286,"companyAlias":"nxp-semiconductors","description":"The IoT Gateway Solution aims to accelerate IoT development needs with integrated, comprehensive and fully documented out-of-the-box guidance and support.\r\nIt includes the NXP Modular IoT Gateway and Modular Edge Node, which are tested and verified for ZigBee® and Thread connectivity, as well as secure cloud communications through Wi-Fi, Ethernet, and cellular, enabling access to cloud services.","shortDescription":"A complete development platform that brings together the building blocks for secure, production-ready IoT systems.\r\n","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":5,"sellingCount":17,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"NXP Semiconductors IoT Gateway Solution","keywords":"","description":"The IoT Gateway Solution aims to accelerate IoT development needs with integrated, comprehensive and fully documented out-of-the-box guidance and support.\r\nIt includes the NXP Modular IoT Gateway and Modular Edge Node, which are tested and verified for ZigBee®","og:title":"NXP Semiconductors IoT Gateway Solution","og:description":"The IoT Gateway Solution aims to accelerate IoT development needs with integrated, comprehensive and fully documented out-of-the-box guidance and support.\r\nIt includes the NXP Modular IoT Gateway and Modular Edge Node, which are tested and verified for ZigBee®","og:image":"https://old.roi4cio.com/fileadmin/user_upload/NXP_Semiconductors_IoT_GATEWAY_Solution.png"},"eventUrl":"","translationId":4905,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4910,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Opengear_logo.png","logo":true,"scheme":false,"title":"OpenGear IoT Gateways","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"opengear-iot-gateways","companyTitle":"Opengear","companyTypes":["vendor"],"companyId":5292,"companyAlias":"opengear","description":"The arrival of the Internet of Things (IoT) requires a new level of resilience in the data center and edge networking equipment. As the number of connected objects continues to grow and the IoT becomes ubiquitous, organizations in almost every industry will have to bolster their networks with fog computing and cellular out-of-band management solutions.\r\nManage your mission-critical endpoints — wherever they are — and keep them connected at all times via 3G and 4G LTE.\r\nBy moving certain compute resources away from the center and closer to the edge of a network, organizations will be able to more effectively handle all of their data — no matter where it’s coming from or going to. Routers, switches and other hardened gateway devices that will be the core part of a fog computing deployment can help to effectively facilitate data handling and backhaul.\r\nOpengear’s smart network management solutions give IT admins the ability to use robust and always-available 3G and 4G LTE connections instead of legacy wireline modems. Your team will be able to remotely manage and oversee the switches, routers and other endpoints that form the core of any fog computing arrangement. This way, even a small group of IT admins can ensure that any number of mission-critical endpoints, no matter where they’re located, are working well at all times.\r\nBy pairing an investment in the IoT with <span style=\"font-weight: bold;\">Opengear’s SmartOOB™</span> management, organizations can rest assured that the network at the heart of their newly connected operations will function properly and that problems can be quickly identified and easily resolved.\r\n<span style=\"font-weight: bold;\">Benefits:</span>\r\n<ul><li>Always-on connectivity through mainline connections and embedded 4G LTE</li><li>Ability to reimage and reboot devices remotely, even when primary connections are down</li><li>High- and low-density models to support any sized deployment</li><li>Scalability to support accelerating IoT network of devices</li><li>Device agnostic to support any endpoint or beacon manufacturer</li></ul>\r\n<span style=\"font-weight: bold;\">Products:</span>\r\n<ul><li>ACM7000-L – Resilience Gateway</li><li>ACM7000 Remote Site Gateway</li><li>IM7200 Infrastructure Manager</li></ul>","shortDescription":"Keeping Your “Connected Things” Connected.\r\n","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":0,"sellingCount":17,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"OpenGear IoT Gateways","keywords":"","description":"The arrival of the Internet of Things (IoT) requires a new level of resilience in the data center and edge networking equipment. As the number of connected objects continues to grow and the IoT becomes ubiquitous, organizations in almost every industry will ha","og:title":"OpenGear IoT Gateways","og:description":"The arrival of the Internet of Things (IoT) requires a new level of resilience in the data center and edge networking equipment. As the number of connected objects continues to grow and the IoT becomes ubiquitous, organizations in almost every industry will ha","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Opengear_logo.png"},"eventUrl":"","translationId":4911,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":513,"title":"Networking","alias":"networking","description":" Networking hardware, also known as network equipment or computer networking devices, are electronic devices which are required for communication and interaction between devices on a computer network. Specifically, they mediate data transmission in a computer network. Units which are the last receiver or generate data are called hosts or data terminal equipment.\r\nNetworking devices may include gateways, routers, network bridges, modems, wireless access points, networking cables, line drivers, switches, hubs, and repeaters; and may also include hybrid network devices such as multilayer switches, protocol converters, bridge routers, proxy servers, firewalls, network address translators, multiplexers, network interface controllers, wireless network interface controllers, ISDN terminal adapters and other related hardware.\r\nThe most common kind of networking hardware today is a copper-based Ethernet adapter which is a standard inclusion on most modern computer systems. Wireless networking has become increasingly popular, especially for portable and handheld devices.\r\nOther networking hardware used in computers includes data center equipment (such as file servers, database servers and storage areas), network services (such as DNS, DHCP, email, etc.) as well as devices which assure content delivery.\r\nTaking a wider view, mobile phones, tablet computers and devices associated with the internet of things may also be considered networking hardware. As technology advances and IP-based networks are integrated into building infrastructure and household utilities, network hardware will become an ambiguous term owing to the vastly increasing number of network capable endpoints.","materialsDescription":" <span style=\"font-weight: bold;\">What is network equipment?</span>\r\nNetwork equipment - devices necessary for the operation of a computer network, for example: a router, switch, hub, patch panel, etc. You can distinguish between active and passive network equipment.\r\n<span style=\"font-weight: bold;\">What is an active network equipment?</span>\r\nActive networking equipment is equipment followed by some “smart” feature. That is, a router, switch (switch), etc. are active network equipment.\r\n<span style=\"font-weight: bold;\">What is passive network equipment?</span>\r\nPassive network equipment - equipment not endowed with &quot;intellectual&quot; features. For example - cable system: cable (coaxial and twisted pair (UTP/STP)), plug / socket (RG58, RJ45, RJ11, GG45), repeater (repeater), patch panel, hub (hub), balun (balun) for coaxial cables (RG-58), etc. Also, passive equipment can include mounting cabinets and racks, telecommunication cabinets.\r\n<span style=\"font-weight: bold;\">What are the main network components?</span>\r\nThe main components of the network are workstations, servers, transmission media (cables) and network equipment.\r\n<span style=\"font-weight: bold;\">What are workstations?</span>\r\nWorkstations are network computers where network users implement application tasks.\r\n<span style=\"font-weight: bold;\">What are network servers?</span>\r\nNetwork servers - hardware and software systems that perform the functions of controlling the distribution of network shared resources. A server can be any computer connected to the network on which the resources used by other devices on the local network are located. As the server hardware, fairly powerful computers are used.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Networking.png"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":5431,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Crayonic.png","logo":true,"scheme":false,"title":"Crayonic Key Vault","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"crayonic-key-vault","companyTitle":"Crayonic","companyTypes":["supplier","vendor"],"companyId":6573,"companyAlias":"crayonic","description":"With <b>Crayonic KeyVault™</b> we enable next-generation security for authentication of users, storing digital assets, and e-signing documents. Organizations and individuals can replace all passwords with a simple written or spoken PIN and protect all personal cryptographic keys and secrets in one simple-to-use device. ​ <b>Crayonic KeyVault™</b> provides unrivaled usability and highest security while incorporating the Proof-of-Free-Will™ \r\n<b>Multi-factor Authentication</b>\r\nSecurely authenticate to any FIDO2 compatible system without username and password. \r\n<b>Cryptocurrency Hardware Wallet</b>\r\nStore cryptocurrency in an offline hardware wallet protected by multiple biometric factors and the Proof-of-Free-Will.\r\n<b>Certified E-signatures</b>\r\nSign electronic documents on the screen of mobile device with certified electronic signature.","shortDescription":"Say goodbye to passwords\r\n","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":2,"sellingCount":14,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Crayonic Key Vault","keywords":"","description":"With <b>Crayonic KeyVault™</b> we enable next-generation security for authentication of users, storing digital assets, and e-signing documents. Organizations and individuals can replace all passwords with a simple written or spoken PIN and protect all perso","og:title":"Crayonic Key Vault","og:description":"With <b>Crayonic KeyVault™</b> we enable next-generation security for authentication of users, storing digital assets, and e-signing documents. Organizations and individuals can replace all passwords with a simple written or spoken PIN and protect all perso","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Crayonic.png"},"eventUrl":"","translationId":5430,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3384,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Arrow_Data.JPG","logo":true,"scheme":false,"title":"Somerdata Arow Data Diode","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"arow-data-diode","companyTitle":"Somerdata","companyTypes":["supplier","vendor"],"companyId":5341,"companyAlias":"somerdata","description":"AROW is a Unidirectional Router, also sometimes known as a Data Diode due to its ability to entirely block network trac in one direction.\r\nWhile Data Diodes have been around&nbsp; a long time, they sometimes have been regarded as a slow and unreliable. Very often,&nbsp; data could be lost in the process of sending and receiving and as a result users on the receiver side have had incomplete or missing data.\r\nSomerdata has taken its expertise in intelligence and security solutions, to create a third generation device which is&nbsp; faster, highly&nbsp; reliable, and&nbsp; which allows receiving of data in the same structure as it was sent, preventing&nbsp; data loss.\r\n<span style=\"font-weight: bold;\">Why would you need AROW?</span> \r\nAROW Advanced Reliable Optical Wormhole can protect governmental and commercial organisations against people who they might not&nbsp; suspect as potential threats to their valuable data.\r\nTwo of&nbsp; the biggest threats for organisations,&nbsp; governments and corporations in network and data systems are internal sabotage or accidental exltration by employees who have easy access to vital data. \r\nWhile rewalls can be effective, they can be circumvented by determined attackers, poorly-trained employees or internal malcontents.\r\nAROW is not a substitute for a rewall, it is an additional layer of protection against data theft and cyber attacks.<br />AROW is extremely effective in providing controlled access between highsecurity and low-security networks, in process control environments to allow only authorised status information to be accessed. AROW is also effective against trojans and phishing attacks&nbsp; aimed at stealthy data theft since there is no physical path for data to leave the network.\r\nDesigned to EAL standards, this Data Diode meets the most stringent of security requirements.<br />Guard your organisation from&nbsp; cyber attacks and sabotage. \r\nAROW is available in 3 options of 2 variants, optimised for streaming or file transfer:\r\n<ul><li>An entry level single channel</li></ul>\r\n<ul><li>An enterprise level dual-channel</li></ul>\r\n<ul><li>A high security level fully-redundant </li></ul>\r\nAll versions feature single-direction isolating GBE performance, Copper and Fibre TCP/UDP over IP connectivity and high quality construction.\r\nAROW is optimised for le transfer over TCP&nbsp; and can be used in conjunction with software lters and&nbsp; or with the supplied AROWBftp software.&nbsp; This opensource Python code allows automatic management of le transfers, TCP and UDP&nbsp; stream data, web-site transmission etc and can be easily audited, extended or customised to your specic needs. Customisation can be done either by us or your own developers or system administrators.\r\nAROW can be also used as a direct connection for existing TCP/UDP/Multicast streams utilising the ultra-high speed capability of the dedicated hardware.\r\nAROW is designed and manufactured in the UK","shortDescription":"AROW is a Unidirectional Router, also sometimes known as a Data Diode due to its ability to entirely block network trac in one direction. ","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":10,"sellingCount":19,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Somerdata Arow Data Diode","keywords":"","description":"AROW is a Unidirectional Router, also sometimes known as a Data Diode due to its ability to entirely block network trac in one direction.\r\nWhile Data Diodes have been around&nbsp; a long time, they sometimes have been regarded as a slow and unreliable. Very of","og:title":"Somerdata Arow Data Diode","og:description":"AROW is a Unidirectional Router, also sometimes known as a Data Diode due to its ability to entirely block network trac in one direction.\r\nWhile Data Diodes have been around&nbsp; a long time, they sometimes have been regarded as a slow and unreliable. Very of","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Arrow_Data.JPG"},"eventUrl":"","translationId":3385,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":5,"title":"Security Software","alias":"security-software","description":" Computer security software or cybersecurity software is any computer program designed to enhance information security. Security software is a broad term that encompasses a suite of different types of software that deliver data and computer and network security in various forms. \r\nSecurity software can protect a computer from viruses, malware, unauthorized users and other security exploits originating from the Internet. Different types of security software include anti-virus software, firewall software, network security software, Internet security software, malware/spamware removal and protection software, cryptographic software, and more.\r\nIn end-user computing environments, anti-spam and anti-virus security software is the most common type of software used, whereas enterprise users add a firewall and intrusion detection system on top of it. \r\nSecurity soft may be focused on preventing attacks from reaching their target, on limiting the damage attacks can cause if they reach their target and on tracking the damage that has been caused so that it can be repaired. As the nature of malicious code evolves, security software also evolves.<span style=\"font-weight: bold; \"></span>\r\n<span style=\"font-weight: bold; \">Firewall. </span>Firewall security software prevents unauthorized users from accessing a computer or network without restricting those who are authorized. Firewalls can be implemented with hardware or software. Some computer operating systems include software firewalls in the operating system itself. For example, Microsoft Windows has a built-in firewall. Routers and servers can include firewalls. There are also dedicated hardware firewalls that have no other function other than protecting a network from unauthorized access.\r\n<span style=\"font-weight: bold; \">Antivirus.</span> Antivirus solutions work to prevent malicious code from attacking a computer by recognizing the attack before it begins. But it is also designed to stop an attack in progress that could not be prevented, and to repair damage done by the attack once the attack abates. Antivirus software is useful because it addresses security issues in cases where attacks have made it past a firewall. New computer viruses appear daily, so antivirus and security software must be continuously updated to remain effective.\r\n<span style=\"font-weight: bold; \">Antispyware.</span> While antivirus software is designed to prevent malicious software from attacking, the goal of antispyware software is to prevent unauthorized software from stealing information that is on a computer or being processed through the computer. Since spyware does not need to attempt to damage data files or the operating system, it does not trigger antivirus software into action. However, antispyware software can recognize the particular actions spyware is taking by monitoring the communications between a computer and external message recipients. When communications occur that the user has not authorized, antispyware can notify the user and block further communications.\r\n<span style=\"font-weight: bold; \">Home Computers.</span> Home computers and some small businesses usually implement&nbsp; security software at the desktop level - meaning on the PC itself. This category of computer security and protection, sometimes referred to as end-point security, remains resident, or continuously operating, on the desktop. Because the software is running, it uses system resources, and can slow the computer's performance. However, because it operates in real time, it can react rapidly to attacks and seek to shut them down when they occur.\r\n<span style=\"font-weight: bold; \">Network Security.</span> When several computers are all on the same network, it's more cost-effective to implement security at the network level. Antivirus software can be installed on a server and then loaded automatically to each desktop. However firewalls are usually installed on a server or purchased as an independent device that is inserted into the network where the Internet connection comes in. All of the computers inside the network communicate unimpeded, but any data going in or out of the network over the Internet is filtered trough the firewall.<br /><br /><br />","materialsDescription":"<h1 class=\"align-center\"> <span style=\"font-weight: normal; \">What is IT security software?</span></h1>\r\nIT security software provides protection to businesses’ computer or network. It serves as a defense against unauthorized access and intrusion in such a system. It comes in various types, with many businesses and individuals already using some of them in one form or another.\r\nWith the emergence of more advanced technology, cybercriminals have also found more ways to get into the system of many organizations. Since more and more businesses are now relying their crucial operations on software products, the importance of security system software assurance must be taken seriously – now more than ever. Having reliable protection such as a security software programs is crucial to safeguard your computing environments and data. \r\n<p class=\"align-left\">It is not just the government or big corporations that become victims of cyber threats. In fact, small and medium-sized businesses have increasingly become targets of cybercrime over the past years. </p>\r\n<h1 class=\"align-center\"><span style=\"font-weight: normal; \">What are the features of IT security software?</span></h1>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Automatic updates. </span>This ensures you don’t miss any update and your system is the most up-to-date version to respond to the constantly emerging new cyber threats.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Real-time scanning.</span> Dynamic scanning features make it easier to detect and infiltrate malicious entities promptly. Without this feature, you’ll risk not being able to prevent damage to your system before it happens.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Auto-clean.</span> A feature that rids itself of viruses even without the user manually removing it from its quarantine zone upon detection. Unless you want the option to review the malware, there is no reason to keep the malicious software on your computer which makes this feature essential.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Multiple app protection.</span> This feature ensures all your apps and services are protected, whether they’re in email, instant messenger, and internet browsers, among others.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application level security.</span> This enables you to control access to the application on a per-user role or per-user basis to guarantee only the right individuals can enter the appropriate applications.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Role-based menu.</span> This displays menu options showing different users according to their roles for easier assigning of access and control.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Row-level (multi-tenant) security.</span> This gives you control over data access at a row-level for a single application. This means you can allow multiple users to access the same application but you can control the data they are authorized to view.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Single sign-on.</span> A session or user authentication process that allows users to access multiple related applications as long as they are authorized in a single session by only logging in their name and password in a single place.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">User privilege parameters.</span> These are customizable features and security as per individual user or role that can be accessed in their profile throughout every application.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application activity auditing.</span> Vital for IT departments to quickly view when a user logged in and off and which application they accessed. Developers can log end-user activity using their sign-on/signoff activities.</li></ul>\r\n<p class=\"align-left\"><br /><br /><br /><br /></p>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Software.png"},{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3388,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/logo_eXMeritus.JPG","logo":true,"scheme":false,"title":"eXMeritus HardwareWall","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"exmeritus-hardwarewall","companyTitle":"eXMeritus Software","companyTypes":["supplier","vendor"],"companyId":5348,"companyAlias":"exmeritus-software","description":"&nbsp;Boeing eXMeritus has designed HardwareWall™ as a Secure Data Transfer System and an off-the-shelf Controlled Interface that meets and exceeds all mission and information assurance requirements for the world’s highest-level security directives. These systems are the only bi-directional, cross-domain solutions in the market to have been deployed and UCDMO-certified in PL-3 (SECRET to SECRET), PL-4 (TOP SECRET to boeing2SECRET) and PL-5 (TOP SECRET to UNCLASS) environments and continue to operate and evolve to meet ever changing requirements and threats.\r\nBy choosing HardwareWall™, organizations have realized the benefits of implementing a system that was designed with the needs and requirements of the community in mind. \r\n<span style=\"font-weight: bold;\">HardwareWall Benefits:</span>\r\n\r\n<ul><li>Broad platform support in SELinux®</li></ul>\r\n<ul><li>Highly configurable and modular to allow interconnection of multiple classifications, programs, compartments, and countries</li></ul>\r\n<ul><li>Rapid deployment of a proven system</li></ul>\r\n<ul><li>Easily integrated into existing systems and workflows</li></ul>\r\n<ul><li>Cost competitive to fit within budgetary constraints</li></ul>\r\n<ul><li>Allows local development of rule sets and integration of applications</li></ul>\r\n<ul><li>Complete solutions incorporating content review, data labelling, MAC, RBAC, audit, etc. and high-speed one-way transfer (10Gb Ethernet)</li></ul>\r\n\r\n","shortDescription":"HardwareWall™ is a secure data transfer system and an off-the-shelf controlled interface that meets and exceeds all mission and information assurance requirements","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":18,"sellingCount":7,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"eXMeritus HardwareWall","keywords":"","description":"&nbsp;Boeing eXMeritus has designed HardwareWall™ as a Secure Data Transfer System and an off-the-shelf Controlled Interface that meets and exceeds all mission and information assurance requirements for the world’s highest-level security directives. These syst","og:title":"eXMeritus HardwareWall","og:description":"&nbsp;Boeing eXMeritus has designed HardwareWall™ as a Secure Data Transfer System and an off-the-shelf Controlled Interface that meets and exceeds all mission and information assurance requirements for the world’s highest-level security directives. These syst","og:image":"https://old.roi4cio.com/fileadmin/user_upload/logo_eXMeritus.JPG"},"eventUrl":"","translationId":3389,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4949,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Secure_Xchange_Network.png","logo":true,"scheme":false,"title":"Seclab Secure Xchange Network","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"seclab-secure-xchange-network","companyTitle":"Seclab","companyTypes":["supplier","vendor"],"companyId":5319,"companyAlias":"seclab","description":"<span style=\"font-weight: bold;\">FILE TRANSFER FEATURES:</span>\r\n<ul><li>Software and firmware secure updates</li><li>Operational Technology updates</li></ul>\r\n<span style=\"font-weight: bold;\">OTHER FEATURES:</span>\r\n<ul><li>Logs Transfers</li><li>Industrial Processes Supervision</li><li>Database Replication</li></ul>","shortDescription":"Provide your critical network with the highest end-to-end security.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":17,"sellingCount":7,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Seclab Secure Xchange Network","keywords":"","description":"<span style=\"font-weight: bold;\">FILE TRANSFER FEATURES:</span>\r\n<ul><li>Software and firmware secure updates</li><li>Operational Technology updates</li></ul>\r\n<span style=\"font-weight: bold;\">OTHER FEATURES:</span>\r\n<ul><li>Logs Transfers</li><li>Industrial P","og:title":"Seclab Secure Xchange Network","og:description":"<span style=\"font-weight: bold;\">FILE TRANSFER FEATURES:</span>\r\n<ul><li>Software and firmware secure updates</li><li>Operational Technology updates</li></ul>\r\n<span style=\"font-weight: bold;\">OTHER FEATURES:</span>\r\n<ul><li>Logs Transfers</li><li>Industrial P","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Secure_Xchange_Network.png"},"eventUrl":"","translationId":4950,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4953,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/sec_technologies.png","logo":true,"scheme":false,"title":"Falcon 4G","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"falcon-4g","companyTitle":"SEC Technologies","companyTypes":["vendor"],"companyId":5321,"companyAlias":"sec-technologies","description":"<span style=\"font-weight: bold;\">Falcon 4G</span> is 4th generation of laser-based CBRN stand-off detectors, that can detect, identify and quantify chemical warfare agents and toxic industrial chemicals using absorption of laser radiation caused by molecules of agents and biological warfare agents by evaluating particle size using DISC technology.\r\n<ul><li>Active laser technology- 2 lasers</li><li>Battle field-proven</li><li>Long detection range</li><li>High sensitivity</li><li>No calibration</li></ul>","shortDescription":"Falcon 4G is 4th generation of laser-based CBRN stand-off detectors.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":19,"sellingCount":6,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Falcon 4G","keywords":"","description":"<span style=\"font-weight: bold;\">Falcon 4G</span> is 4th generation of laser-based CBRN stand-off detectors, that can detect, identify and quantify chemical warfare agents and toxic industrial chemicals using absorption of laser radiation caused by molecules o","og:title":"Falcon 4G","og:description":"<span style=\"font-weight: bold;\">Falcon 4G</span> is 4th generation of laser-based CBRN stand-off detectors, that can detect, identify and quantify chemical warfare agents and toxic industrial chemicals using absorption of laser radiation caused by molecules o","og:image":"https://old.roi4cio.com/fileadmin/user_upload/sec_technologies.png"},"eventUrl":"","translationId":4954,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3430,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/akua_logo.png","logo":true,"scheme":false,"title":"The AKUA Cloud Platform","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"the-akua-cloud-platform","companyTitle":"AKUA","companyTypes":["supplier","vendor"],"companyId":5167,"companyAlias":"akua","description":"With the AKUA Cloud Platform, cargo owner can GPS-track and continuously monitor the progress of intermodal containers. Our devices provide real-time security and environmental sensing, with data reported through telecommunications infrastructure up to the AKUA cloud. This lets cargo owners maintain real-time awareness of their shipments’ location and status, with immediate alerts of any incursion or environmental threshold violation.\r\nWith AKUA, there is no new equipment to buy or manage. The necessary IoT gateway devices, sensors, and device logistics are included in the subscription. A customer’s existing IoT sensors can also be easily integrated into the AKUA Cloud Platform.","shortDescription":"The IoT platform provides persistent environmental monitoring and tracking solutions for intermodal cargo containers, enabling exceptional in-transit visibility of goods and shipments across the globe","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":10,"sellingCount":17,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"The AKUA Cloud Platform","keywords":"","description":"With the AKUA Cloud Platform, cargo owner can GPS-track and continuously monitor the progress of intermodal containers. Our devices provide real-time security and environmental sensing, with data reported through telecommunications infrastructure up to the AKU","og:title":"The AKUA Cloud Platform","og:description":"With the AKUA Cloud Platform, cargo owner can GPS-track and continuously monitor the progress of intermodal containers. Our devices provide real-time security and environmental sensing, with data reported through telecommunications infrastructure up to the AKU","og:image":"https://old.roi4cio.com/fileadmin/user_upload/akua_logo.png"},"eventUrl":"","translationId":3431,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":52,"title":"SaaS - software as a service","alias":"saas-software-as-a-service","description":"<span style=\"font-weight: bold;\">Software as a service (SaaS)</span> is a software licensing and delivery model in which software is licensed on a subscription basis and is centrally hosted. It is sometimes referred to as &quot;on-demand software&quot;, and was formerly referred to as &quot;software plus services&quot; by Microsoft.\r\n SaaS services is typically accessed by users using a thin client, e.g. via a web browser. SaaS software solutions has become a common delivery model for many business applications, including office software, messaging software, payroll processing software, DBMS software, management software, CAD software, development software, gamification, virtualization, accounting, collaboration, customer relationship management (CRM), Management Information Systems (MIS), enterprise resource planning (ERP), invoicing, human resource management (HRM), talent acquisition, learning management systems, content management (CM), Geographic Information Systems (GIS), and service desk management. SaaS has been incorporated into the strategy of nearly all leading enterprise software companies.\r\nSaaS applications are also known as <span style=\"font-weight: bold;\">Web-based software</span>, <span style=\"font-weight: bold;\">on-demand software</span> and<span style=\"font-weight: bold;\"> hosted software</span>.\r\nThe term &quot;Software as a Service&quot; (SaaS) is considered to be part of the nomenclature of cloud computing, along with Infrastructure as a Service (IaaS), Platform as a Service (PaaS), Desktop as a Service (DaaS),managed software as a service (MSaaS), mobile backend as a service (MBaaS), and information technology management as a service (ITMaaS).\r\nBecause SaaS is based on cloud computing it saves organizations from installing and running applications on their own systems. That eliminates or at least reduces the associated costs of hardware purchases and maintenance and of software and support. The initial setup cost for a SaaS application is also generally lower than it for equivalent enterprise software purchased via a site license.\r\nSometimes, the use of SaaS cloud software can also reduce the long-term costs of software licensing, though that depends on the pricing model for the individual SaaS offering and the enterprise’s usage patterns. In fact, it’s possible for SaaS to cost more than traditional software licenses. This is an area IT organizations should explore carefully.<br />SaaS also provides enterprises the flexibility inherent with cloud services: they can subscribe to a SaaS offering as needed rather than having to buy software licenses and install the software on a variety of computers. The savings can be substantial in the case of applications that require new hardware purchases to support the software.<br /><br /><br /><br />","materialsDescription":"<h1 class=\"align-center\"><span style=\"font-weight: normal;\">Who uses SaaS?</span></h1>\r\nIndustry analyst Forrester Research notes that SaaS adoption has so far been concentrated mostly in human resource management (HRM), customer relationship management (CRM), collaboration software (e.g., email), and procurement solutions, but is poised to widen. Today it’s possible to have a data warehouse in the cloud that you can access with business intelligence software running as a service and connect to your cloud-based ERP like NetSuite or Microsoft Dynamics.The dollar savings can run into the millions. And SaaS installations are often installed and working in a fraction of the time of on-premises deployments—some can be ready in hours. \r\nSales and marketing people are likely familiar with Salesforce.com, the leading SaaS CRM software, with millions of users across more than 100,000 customers. Sales is going SaaS too, with apps available to support sales in order management, compensation, quote production and configure, price, quoting, electronic signatures, contract management and more.\r\n<h1 class=\"align-center\"><span style=\"font-weight: normal;\">Why SaaS? Benefits of software as a service</span></h1>\r\n<ul><li><span style=\"font-weight: bold;\">Lower cost of entry</span>. With SaaS solution, you pay for what you need, without having to buy hardware to host your new applications. Instead of provisioning internal resources to install the software, the vendor provides APIs and performs much of the work to get their software working for you. The time to a working solution can drop from months in the traditional model to weeks, days or hours with the SaaS model. In some businesses, IT wants nothing to do with installing and running a sales app. In the case of funding software and its implementation, this can be a make-or-break issue for the sales and marketing budget, so the lower cost really makes the difference.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold;\">Reduced time to benefit/rapid prototyping</span>. In the SaaS model, the software application is already installed and configured. Users can provision the server for the cloud and quickly have the application ready for use. This cuts the time to benefit and allows for rapid demonstrations and prototyping. With many SaaS companies offering free trials, this means a painless proof of concept and discovery phase to prove the benefit to the organization. </li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold;\">Pay as you go</span>. SaaS business software gives you the benefit of predictable costs both for the subscription and to some extent, the administration. Even as you scale, you can have a clear idea of what your costs will be. This allows for much more accurate budgeting, especially as compared to the costs of internal IT to manage upgrades and address issues for an owned instance.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold;\">The SaaS vendor is responsible for upgrades, uptime and security</span>. Under the SaaS model, since the software is hosted by the vendor, they take on the responsibility for maintaining the software and upgrading it, ensuring that it is reliable and meeting agreed-upon service level agreements, and keeping the application and its data secure.&nbsp; While some IT people worry about Software as a Service security outside of the enterprise walls, the likely truth is that the vendor has a much higher level of security than the enterprise itself would provide. Many will have redundant instances in very secure data centers in multiple geographies.&nbsp; Also, the data is being automatically backed up by the vendor, providing additional security and peace of mind. Because of the data center hosting, you’re getting the added benefit of at least some disaster recovery. Lastly, the vendor manages these issues as part of their core competencies—let them.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold;\">Integration and scalability.</span> Most SaaS apps are designed to support some amount of customization for the way you do business. SaaS vendors create APIs to allow connections not only to internal applications like ERPs or CRMs but also to other SaaS providers. One of the terrific aspects of integration is that orders written in the field can be automatically sent to the ERP. Now a salesperson in the field can check inventory through the catalog, write the order in front of the customer for approval, send it and receive confirmation, all in minutes. And as you scale with a SaaS vendor, there’s no need to invest in server capacity and software licenses. </li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold;\">Work anywhere</span>. Since the software is hosted in the cloud and accessible over the internet, users can access it via mobile devices wherever they are connected. This includes checking customer order histories prior to a sales call, as well as having access to real time data and real time order taking with the customer.</li></ul>\r\n<p class=\"align-left\">&nbsp;</p>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SaaS__1_.png"},{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4710,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Endian-logo.jpg","logo":true,"scheme":false,"title":"Endian Industrial IoT Security","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"endian-industrial-iot-security","companyTitle":"Endian","companyTypes":["supplier","vendor"],"companyId":5220,"companyAlias":"endian","description":"<span style=\"font-weight: bold;\">Industrial VPN Connectivity</span>\r\nThe Endian 4i Edge products provide the best and most comprehensive lineup of simple and secure remote access options of any product on the market. These allow you to connect the 4i Edge to virtually any corporate or industrial VPN network to remotely monitor and manage your critical equipment (PLC, HMI, etc.) in real-time. Provide complete Industrial IoT Security to your network.\r\n<span style=\"font-weight: bold;\">Centralized Network Management</span>\r\nCentrally manage all your Endian appliances. Reduce administrator management time and effort and save valuable staff resources with centralized management made easy with Endian Management Center (EMC).\r\n<span style=\"font-weight: bold;\">Remote IoT and M2M Communication</span>\r\nEndian 4i Edge series comes with all new Industrial IoT and M2M features to enable you to better communicate with your remote equipment in real-time. The main feature uses a technology called Serial over IP which allows you to simply and securely access a remote serial port connection to your PLC in the field from anywhere in the world.\r\n<span style=\"font-weight: bold;\">Unlimited Connectivity</span>\r\nThe Endian 4i Edge series supports virtually any kind of Internet connection making it extremely adaptable to suit almost any project requirement. All of these connectivity options ensure your remote endpoints and networks have the highest levels of availability which keeps your business running smoothly.\r\n<span style=\"font-weight: bold;\">Deploy Anywhere (Even Behind Firewalls)</span>\r\nEndian can be deployed virtually anywhere usually with little to no disruption to the existing infrastructure. Our VPN technology allows our 4i appliances to get connected even behind existing corporate firewalls.\r\n<span style=\"font-weight: bold;\">NERC CIP Compliance (Whitepaper)</span>\r\nDownload our new whitepaper today to learn how the Endian solutions can help you to meet the relevant components of NERC CIP standards.&nbsp; This detailed guide will show you all the ways that Endian partners and products can help your business with compliance.\r\n\r\n<span style=\"font-weight: bold;\">Endian 4i - Industrial VPN Router Features</span>\r\n<ul><li>Stateful Firewall</li><li>Multi-WAN (with Failover)</li><li>Intrusion Prevention (IPS)</li><li>Centralized Management</li><li>High Availability (Hardware Failover)</li><li>Reporting</li><li>VPN (OpenVPN &amp; IPSec)</li></ul>","shortDescription":"The Endian 4i Edge series brings an unparalleled level of hardware performance and features to the industrial VPN router market.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":10,"sellingCount":9,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Endian Industrial IoT Security","keywords":"","description":"<span style=\"font-weight: bold;\">Industrial VPN Connectivity</span>\r\nThe Endian 4i Edge products provide the best and most comprehensive lineup of simple and secure remote access options of any product on the market. These allow you to connect the 4i Edge to v","og:title":"Endian Industrial IoT Security","og:description":"<span style=\"font-weight: bold;\">Industrial VPN Connectivity</span>\r\nThe Endian 4i Edge products provide the best and most comprehensive lineup of simple and secure remote access options of any product on the market. These allow you to connect the 4i Edge to v","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Endian-logo.jpg"},"eventUrl":"","translationId":4711,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":56,"title":"Router","alias":"router","description":"A router is a networking device that forwards data packets between computer networks. Routers perform the traffic directing functions on the Internet. Data sent through the internet, such as a web page or email, is in the form of data packets. A packet is typically forwarded from one router to another router through the networks that constitute an internetwork (e.g. the Internet) until it reaches its destination node.\r\nA router is connected to two or more data lines from different IP networks. When a data packet comes in on one of the lines, the router reads the network address information in the packet header to determine the ultimate destination. Then, using information in its routing table or routing policy, it directs the packet to the next network on its journey.\r\nThe most familiar type of IP routers are home and small office routers that simply forward IP packets between the home computers and the Internet. An example of a router would be the owner's cable or DSL router, which connects to the Internet through an Internet service provider (ISP). More sophisticated routers, such as enterprise routers, connect large business or ISP networks up to the powerful core routers that forward data at high speed along the optical fiber lines of the Internet backbone.\r\nThe main purpose of a router is to connect multiple networks and forward packets destined either for its own networks or other networks. A router is considered a layer-3 device because its primary forwarding decision is based on the information in the layer-3 IP packet, specifically the destination IP address. When a router receives a packet, it searches its routing table to find the best match between the destination IP address of the packet and one of the addresses in the routing table. Once a match is found, the packet is encapsulated in the layer-2 data link frame for the outgoing interface indicated in the table entry. A router typically does not look into the packet payload,[citation needed] but only at the layer-3 addresses to make a forwarding decision, plus optionally other information in the header for hints on, for example, quality of service (QoS). For pure IP forwarding, a router is designed to minimize the state information associated with individual packets. Once a packet is forwarded, the router does not retain any historical information about the packet.\r\nThe routing table itself can contain information derived from a variety of sources, such as a default or static routes that are configured manually, or dynamic routing protocols where the router learns routes from other routers. A default route is one that is used to route all traffic whose destination does not otherwise appear in the routing table; this is common – even necessary – in small networks, such as a home or small business where the default route simply sends all non-local traffic to the Internet service provider. The default route can be manually configured (as a static route), or learned by dynamic routing protocols, or be obtained by DHCP.\r\nA router can run more than one routing protocol at a time, particularly if it serves as an autonomous system border router between parts of a network that run different routing protocols; if it does so, then redistribution may be used (usually selectively) to share information between the different protocols running on the same router.\r\nBesides making a decision as to which interface a packet is forwarded to, which is handled primarily via the routing table, a router also has to manage congestion when packets arrive at a rate higher than the router can process. Three policies commonly used in the Internet are tail drop, random early detection (RED), and weighted random early detection (WRED). Tail drop is the simplest and most easily implemented; the router simply drops new incoming packets once the length of the queue exceeds the size of the buffers in the router. RED probabilistically drops datagrams early when the queue exceeds a pre-configured portion of the buffer, until a pre-determined max, when it becomes tail drop. WRED requires a weight on the average queue size to act upon when the traffic is about to exceed the pre-configured size, so that short bursts will not trigger random drops.\r\nAnother function a router performs is to decide which packet should be processed first when multiple queues exist. This is managed through QoS, which is critical when Voice over IP is deployed, so as not to introduce excessive latency.\r\nYet another function a router performs is called policy-based routing where special rules are constructed to override the rules derived from the routing table when a packet forwarding decision is made.\r\nRouter functions may be performed through the same internal paths that the packets travel inside the router. Some of the functions may be performed through an application-specific integrated circuit (ASIC) to avoid overhead of scheduling CPU time to process the packets. Others may have to be performed through the CPU as these packets need special attention that cannot be handled by an ASIC.","materialsDescription":" <span style=\"font-weight: bold;\">What Is a Router?</span>\r\nRouters are the nodes that make up a computer network like the internet. The router you use at home is the central node of your home network.\r\nIt functions as an information manager between the internet and all devices that go online (i.e. all devices connected to the router). Generally speaking, routers direct incoming traffic to its destination.\r\nThis also makes your router the first line of security in protecting your home network from malicious online attacks.\r\n<span style=\"font-weight: bold;\">What Does a Router Do?</span>\r\nYour router handles network traffic. For example, to view this article, data packages coding for this website have to transit from our server, through various nodes on the internet, and finally through your router to arrive on your phone or computer. On your device, your browser decodes those data packages to display the article you’re currently reading.\r\nSince a typical household has more than one device that connects to the internet, you need a router to manage the incoming network signals. In other words, your router makes sure that the data packages coding for a website you want to view on your computer aren’t sent to your phone. It does that by using your device’s MAC address.\r\nWhile your router has a unique (external) IP address to receive data packages from servers worldwide, every device on your home network also carries a unique MAC address. Simply put, when you try to access information online, your router maintains a table to keep track of which device requested information from where. Based on this table, your router distributes incoming data packages to the correct recipient.\r\n<span style=\"font-weight: bold;\">What Is the Difference Between Modems and Routers?</span>\r\nA modem turns the proprietary network signal of your ISP (internet service provider) into a standard network signal. In theory, you can choose between multiple ISPs and some of them may use the same delivery route. Your modem knows which signals to read and translate.\r\nThe kind of modem your ISP will provide you with depends on how you’re connecting to the internet. For example, a DSL modem requires a different technology than a cable or fiber optic broadband modem. That’s because one uses the copper wiring of your telephone line, while the others use a coaxial or a fiber optic cable, respectively.\r\nThe DSL modem has to filter and read both the low frequencies that phone and voice data produce, as well as the high frequencies of internet data. Cable modems, on the other hand, have to differentiate between television and internet signals, which are transmitted on different channels, rather than different frequencies. Finally, fiber optic uses pulses of light to transmit information. The modem has to decode these signals into standard data packages.\r\nOnce the modem has turned the ISP’s network signal into data packages, the router can distribute them to the target device.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/Router1.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":513,"title":"Networking","alias":"networking","description":" Networking hardware, also known as network equipment or computer networking devices, are electronic devices which are required for communication and interaction between devices on a computer network. Specifically, they mediate data transmission in a computer network. Units which are the last receiver or generate data are called hosts or data terminal equipment.\r\nNetworking devices may include gateways, routers, network bridges, modems, wireless access points, networking cables, line drivers, switches, hubs, and repeaters; and may also include hybrid network devices such as multilayer switches, protocol converters, bridge routers, proxy servers, firewalls, network address translators, multiplexers, network interface controllers, wireless network interface controllers, ISDN terminal adapters and other related hardware.\r\nThe most common kind of networking hardware today is a copper-based Ethernet adapter which is a standard inclusion on most modern computer systems. Wireless networking has become increasingly popular, especially for portable and handheld devices.\r\nOther networking hardware used in computers includes data center equipment (such as file servers, database servers and storage areas), network services (such as DNS, DHCP, email, etc.) as well as devices which assure content delivery.\r\nTaking a wider view, mobile phones, tablet computers and devices associated with the internet of things may also be considered networking hardware. As technology advances and IP-based networks are integrated into building infrastructure and household utilities, network hardware will become an ambiguous term owing to the vastly increasing number of network capable endpoints.","materialsDescription":" <span style=\"font-weight: bold;\">What is network equipment?</span>\r\nNetwork equipment - devices necessary for the operation of a computer network, for example: a router, switch, hub, patch panel, etc. You can distinguish between active and passive network equipment.\r\n<span style=\"font-weight: bold;\">What is an active network equipment?</span>\r\nActive networking equipment is equipment followed by some “smart” feature. That is, a router, switch (switch), etc. are active network equipment.\r\n<span style=\"font-weight: bold;\">What is passive network equipment?</span>\r\nPassive network equipment - equipment not endowed with &quot;intellectual&quot; features. For example - cable system: cable (coaxial and twisted pair (UTP/STP)), plug / socket (RG58, RJ45, RJ11, GG45), repeater (repeater), patch panel, hub (hub), balun (balun) for coaxial cables (RG-58), etc. Also, passive equipment can include mounting cabinets and racks, telecommunication cabinets.\r\n<span style=\"font-weight: bold;\">What are the main network components?</span>\r\nThe main components of the network are workstations, servers, transmission media (cables) and network equipment.\r\n<span style=\"font-weight: bold;\">What are workstations?</span>\r\nWorkstations are network computers where network users implement application tasks.\r\n<span style=\"font-weight: bold;\">What are network servers?</span>\r\nNetwork servers - hardware and software systems that perform the functions of controlling the distribution of network shared resources. A server can be any computer connected to the network on which the resources used by other devices on the local network are located. As the server hardware, fairly powerful computers are used.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Networking.png"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":5736,"logoURL":"https://old.roi4cio.com/fileadmin/content/DCU_2.0_-_2.png","logo":true,"scheme":false,"title":"Data Capture Unit (DCU)","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":1,"alias":"data-capture-unit-dcu","companyTitle":"Siemens","companyTypes":["vendor"],"companyId":2795,"companyAlias":"siemens","description":"<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">Industrial data diode designed to deliver the highest level of security to OT networks like industrial control systems (ICS) and safety critical infrastructure via physical isolation when there&rsquo;s a need to connect them to a lower security network (IT Networks or Internet) for replication or analytics. </span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">&nbsp;</span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">The DCU is designed and manufactured in Germany, its chip design forces data to flow one-way only using a unique electromagnetic induction design, to collect data and guarantee that there&rsquo;s no physical path for remote access to the OT Network.</span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">&nbsp;</span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">The DCU has a software complement called, OWG (One-way gateway) software, its two agents, a OWG sender capable of data collection of several protocols (FTP, OPC UA, Syslog), filtering and aggregating data in the OT network (Edge) to then push it thru the DCU and a OWG receiver, which receives data from the DCU and can be configured to send it directly to the cloud (AWS or MindSphere) or to another computer in the IT network.</span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">&nbsp;</span></p>\r\n<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">The DCU and OWG are vendor neutral and support Windows or Linux systems.</span></p>","shortDescription":"The DCU enables secure data transfer to IT networks or cloud without compromising the security of OT networks like industrial control systems (ICS) and critical infrastructure.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":5,"sellingCount":5,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Data Capture Unit (DCU)","keywords":"","description":"<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">Industrial data diode designed to deliver the highest level of security to OT networks like industrial control systems (ICS) and safety critical infrastructure via physi","og:title":"Data Capture Unit (DCU)","og:description":"<p class=\"MsoNormal\" style=\"margin-left: 42.55pt;\"><span style=\"mso-ansi-language: EN-US;\">Industrial data diode designed to deliver the highest level of security to OT networks like industrial control systems (ICS) and safety critical infrastructure via physi","og:image":"https://old.roi4cio.com/fileadmin/content/DCU_2.0_-_2.png"},"eventUrl":"","translationId":5736,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":59,"title":"SCADA - Supervisory Control And Data Acquisition","alias":"scada-supervisory-control-and-data-acquisition","description":"<span style=\"font-weight: bold; \">SCADA</span> stands for <span style=\"font-weight: bold; \">Supervisory Control and Data Acquisition</span>, a term which describes the basic functions of a SCADA system. Companies use SCADA systems to control equipment across their sites and to collect and record data about their operations. SCADA is not a specific technology, but a type of application. Any application that gets operating data about a system in order to control and optimise that system is a SCADA application. That application may be a petrochemical distillation process, a water filtration system, a pipeline compressor, or just about anything else.\r\nSCADA solutions typically come in a combination of software and hardware elements, such as&nbsp;programmable logic controllers (PLCs) and remote terminal units (RTUs). Data acquisition in SCADA starts with PLCs and RTUs, which communicate with plant floor equipment such as factory machinery and sensors. Data gathered from the equipment is then sent to the next level, such as a control room, where operators can supervise the PLC and RTU controls using human-machine interfaces (HMIs). HMIs are an important element of SCADA systems. They are the screens that&nbsp;operators&nbsp;use to communicate with the SCADA system.\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">The major components of a SCADA technology include:</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Master Terminal Unit (MTU).</span> It comprises a computer, PLC and a network server that helps MTU to communicate with the RTUs. MTU begins communication, collects and saves data, helps to interface with operators and to communicate data to other systems.</li><li><span style=\"font-weight: bold;\">Remote Terminal Unit (RTU).</span> RTU is used to collect information from these sensors and further sends the data to MTU. RTUs have the storage capacity facility. So, it stores the data and transmits the data when MTU sends the corresponding command.</li><li><span style=\"font-weight: bold;\">Communication Network (defined by its network topology).</span> In general, network means connection. When you tell a SCADA communication network, it is defined as a link between RTU in the field to MTU in the central location. The bidirectional wired or wireless communication channel is used for the networking purpose. Various other communication mediums like fiber optic cables, twisted pair cables, etc. are also used.</li></ul>\r\n<p class=\"align-center\"><span style=\"font-weight: bold; \">Objectives of Supervisory Control and Data Acquisition system</span></p>\r\n<ul><li><span style=\"font-weight: bold;\">Monitor:</span> SCADA control system continuously monitors the physical parameters</li><li><span style=\"font-weight: bold;\">Measure:</span> It measures the parameter for processing</li><li><span style=\"font-weight: bold;\">Data Acquisition:</span> It acquires data from RTU, data loggers, etc</li><li><span style=\"font-weight: bold;\">Data Communication:</span> It helps to communicate and transmit a large amount of data between MTU and RTU units</li><li><span style=\"font-weight: bold;\">Controlling:</span> Online real-time monitoring and controlling of the process</li><li><span style=\"font-weight: bold;\">Automation:</span> It helps for automatic transmission and functionality</li></ul>\r\n\r\n","materialsDescription":"<h1 class=\"align-center\">Who Uses SCADA?</h1>\r\nSCADA systems are used by industrial organizations and companies in the public and private sectors to control and maintain efficiency, distribute data for smarter decisions, and communicate system issues to help mitigate downtime. Supervisory control systems work well in many different types of enterprises because they can range from simple configurations to large, complex installations. They are the backbone of many modern industries, including:\r\n<ul><li>Energy</li><li>Food and beverage</li><li>Manufacturing</li><li>Oil and gas</li><li>Power</li><li>Recycling</li><li>Transportation</li><li>Water and waste water</li><li>And many more</li></ul>\r\nVirtually anywhere you look in today's world, there is some type of SCADA monitoring system running behind the scenes: maintaining the refrigeration systems at the local supermarket, ensuring production and safety at a refinery, achieving quality standards at a waste water treatment plant, or even tracking your energy use at home, to give a few examples. Effective SCADA systems can result in significant savings of time and money. Numerous case studies have been published highlighting the benefits and savings of using a modern SCADA software.\r\n<h1 class=\"align-center\">Benefits of using SCADA software</h1>\r\nUsing modern SCADA software provides numerous benefits to businesses, and helps companies make the most of those benefits. Some of these advantages include:\r\n<span style=\"font-weight: bold; \">Easier engineering:</span> An advanced supervisory control application such provides easy-to-locate tools, wizards, graphic templates and other pre-configured elements, so engineers can create automation projects and set parameters quickly, even if they don't have programming experience. In addition, you can also easily maintain and expand existing applications as needed. The ability to automate the engineering process allows users, particularly system integrators and original equipment manufacturers (OEM), to set up complex projects much more efficiently and accurately.\r\n<span style=\"font-weight: bold; \">Improved data management:</span> A high-quality SCADA system makes it easier to collect, manage, access and analyze your operational data. It can enable automatic data recording and provide a central location for data storage. Additionally, it can transfer data to other systems such as MES and ERP as needed. \r\n<span style=\"font-weight: bold; \">Greater visibility:</span> One of the main advantages of using SCADA software is the improvement in visibility into your operations. It provides you with real-time information about your operations and enables you to conveniently view that information via an HMI. SCADA monitoring can also help in generating reports and analyzing data.\r\n<span style=\"font-weight: bold; \">Enhanced efficiency:</span> A SCADA system allows you to streamline processes through automated actions and user-friendly tools. The data that SCADA provides allows you to uncover opportunities for improving the efficiency of the operations, which can be used to make long-term changes to processes or even respond to real-time changes in conditions.\r\n<span style=\"font-weight: bold; \">Increased usability:</span> SCADA systems enable workers to control equipment more quickly, easily and safely through an HMI. Rather than having to control each piece of machinery manually, workers can manage them remotely and often control many pieces of equipment from a single location. Managers, even those who are not currently on the floor, also gain this capability.\r\n<span style=\"font-weight: bold; \">Reduced downtime:</span> A SCADA system can detect faults at an early stage and push instant alerts to the responsible personnel. Powered by predictive analytics, a SCADA system can also inform you of a potential issue of the machinery before it fails and causes larger problems. These features can help improve the overall equipment effectiveness (OEE) and reduce the amount of time and cost on troubleshooting and maintenance.\r\n<span style=\"font-weight: bold;\">Easy integration:</span> Connectivity to existing machine environments is key to removing data silos and maximizing productivity. \r\n<span style=\"font-weight: bold;\">Unified platform:</span>All of your data is also available in one platform, which helps you to get a clear overview of your operations and take full advantage of your data. All users also get real-time updates locally or remotely, ensuring everyone on your team is on the same page.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/SCADA__-_Supervisory_Control_And_Data_Acquisition.png"},{"id":223,"title":"Data Access, Analysis, and Delivery Software","alias":"data-access-analysis-and-delivery-software","description":" Data access, analysis and delivery software are end-user oriented tools for ad hoc data access, analysis and reporting as well as production reporting. These products are most commonly used by information consumers or power users rather than professional programmers.\r\nThe processing and analysis of group data is a flexible, iterative method for processing and analyzing data to efficiently provide predictive analytics solutions and intelligent applications. This allows you to improve learning and teamwork. It contains selected recommendations and structures from Microsoft and other developers in the industry that ensure the successful implementation of data processing and analysis solutions. All this is to help companies take full advantage of their analytics software.","materialsDescription":"<span style=\"font-weight: bold; \">Data access</span>\r\nData access is a generic term referring to a process which has both an IT-specific meaning and other connotations involving access rights in a broader legal and/or political sense. In the former it typically refers to software and activities related to storing, retrieving, or acting on data housed in a database or other repository. Two fundamental types of data access exist:\r\n<ol><li>sequential access (as in magnetic tape, for example)</li><li>random access (as in indexed media)</li></ol>\r\nData access crucially involves authorization to access different data repositories. Data access can help distinguish the abilities of administrators and users. For example, administrators may have the ability to remove, edit and add data, while general users may not even have &quot;read&quot; rights if they lack access to particular information.\r\nHistorically, each repository (including each different database, file system, etc.), might require the use of different methods and languages, and many of these repositories stored their content in different and incompatible formats.\r\nOver the years standardized languages, methods, and formats, have developed to serve as interfaces between the often proprietary, and always idiosyncratic, specific languages and methods. Such standards include SQL (1974- ), ODBC (ca 1990- ), JDBC, XQJ, ADO.NET, XML, XQuery, XPath (1999- ), and Web Services.\r\nSome of these standards enable translation of data from unstructured (such as HTML or free-text files) to structured (such as XML or SQL).\r\nStructures such as connection strings and DBURLs[1] can attempt to standardise methods of connecting to databases.\r\n<span style=\"font-weight: bold; \">A program for data analysis</span>\r\nA data analysis program is a specially developed software that can analyze any information. This is usually a database program. It is within the database that you can store any information in any amount. A functional program allows incoming and stored data to analyze. Software development can be done for any tasks, which means that the program for data analysis can be customized for any activity. If, for example, you have a trade organization, then your data analysis program will analyze products, customers, funds, product balance, and more.\r\n<span style=\"font-weight: bold;\">On-demand software delivery</span>\r\nA type of software delivery service where the software is provided to the customer through a network (such as the Internet) as a service. On-demand software delivery is also called software on-demand. The terms on-demand software and Software as a Service (SaaS) are often used interchangeably.\r\nData access, analysis and delivery software are end-user oriented tools for ad hoc data access, analysis and reporting as well as production reporting.&nbsp; These products are most commonly used by information consumers or power users rather than professional programmers.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/Data_Access__Analysis__and_Delivery_Software1.png"},{"id":461,"title":"Data Diode","alias":"data-diode","description":"A unidirectional network (also referred to as a unidirectional gateway or data diode) is a network appliance or device that allows data to travel in only one direction. Data diodes can be found most commonly in high-security environments, such as defense, where they serve as connections between two or more networks of differing security classifications. Given the rise of Industrial IoT and Digitization, this technology can now be found at the industrial control level for such facilities as nuclear power plants, power generation and safety-critical systems like railway networks.<br />After years of development, the use of data diodes has increased, creating two variations:\r\n<ul><li>Data Diode: more often used to refer to the simple hardware version that physically enforces data to flow in only one direction.</li><li>Unidirectional Gateway: Used to describe a more sophisticated device that typically has a computer on both its critical and open side. Unidirectional gateways are a combination of hardware and software. The hardware (data diode) permits data to flow from one network to another but is physically unable to send any information at all back into the source network. The software replicates databases and emulates protocol servers and devices, enabling compatibility with existing network protocols, allowing organizations to gain their benefits without changes to their existing systems.</li></ul>\r\nOnce only commonly found in high-security military environments, unidirectional gateways are now becoming widely spread in sectors like Oil &amp; Gas, water/wastewater, airplanes (between flight control units and in-flight entertainment systems), manufacturing and cloud connectivity for Industrial IoT primarily as a result of new regulations, increased demand and big industrial powerhouses. These industries/sectors and betting on this technology, which has had the effect of lowering the technology's core cost.","materialsDescription":"<span style=\"font-weight: bold;\">What Is Data Diode Technology &amp; How Does It Work?</span>\r\nToday's business environment is increasingly digital and more vulnerable than ever to a cyber attack. Because of this, various network security technologies have been developed to protect organizational data and infrastructures. One of the most effective of these modern technologies is the data diode. Although it is one of the most effective network security tools available, you may not have heard of this technology and know little of what it does. Below, you'll find a description of what data diode technology is and how it works.\r\n<span style=\"font-weight: bold;\">What Is Data Diode Technology?</span>\r\nA data diode is a communication device that enables the safe, one-way transfer of data between segmented networks. Intelligent data diode design maintains physical and electrical separation of source and destination networks, establishing a non-routable, completely closed one-way data transfer protocol between networks. Intelligent data diodes effectively eliminate external points of entry to the sending system, preventing intruders and contagious elements from infiltrating the network. Securing all of a network’s data outflow with data diodes makes it impossible for an insecure or hostile network to pass along malware, access your system, or accidentally make harmful changes.\r\nData diodes allow companies to send process data in real time to information management systems for use in financial, customer service, and management decisions — without compromising the security of your network. This protects valuable information and network infrastructure from theft, destruction, tampering, and human error, mitigating the potential loss of thousands of dollars and countless hours of work.\r\n<span style=\"font-weight: bold;\">How Does Data Diode Technology Work?</span>\r\nA &quot;diode&quot; is an electronic component that only allows current to flow in one direction. Similarly, data diode technology lets information flow safely in only one direction, from secure areas to less secure systems, without permitting reverse access. A data diode also creates a physical barrier or “air gap” between the two points. This one-way connection prevents data leakage, eliminates the threat of malware, and fully protects the process control network. Moreover, a single data diode can handle data transfers from multiple servers or devices simultaneously, without bottlenecking.\r\n<span style=\"font-weight: bold;\">Where is it used?</span>\r\nIt’s typically used to guarantee information security or protection of critical digital systems, such as industrial control systems, from cyber attacks. While the use of these devices is common in high-security environments such as defense, where they serve as connections between two or more networks of differing security classifications, the technology is also being used to enforce one-way communications outbound from critical digital systems to untrusted networks connected to the Internet.\r\nThe physical nature of unidirectional networks only allows data to pass from one side of a network connection to another, and not the other way around. This can be from the &quot;low side&quot; or untrusted network to the &quot;high side&quot; or trusted network or vice versa. In the first case, data in the high side network is kept confidential and users retain access to data from the low side. Such functionality can be attractive if sensitive data is stored on a network which requires connectivity with the Internet: the high side can receive Internet data from the low side, but no data on the high side is accessible to Internet-based intrusion. In the second case, a safety-critical physical system can be made accessible for online monitoring, yet be insulated from all Internet-based attacks that might seek to cause physical damage. In both cases, the connection remains unidirectional even if both the low and the high network are compromised, as the security guarantees are physical in nature.\r\nThere are two general models for using unidirectional network connections. In the classical model, the purpose of the data diode is to prevent the export of classified data from a secure machine while allowing the import of data from an insecure machine. In the alternative model, the diode is used to allow export of data from a protected machine while preventing attacks on that machine.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Data_Diode.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":532,"title":"Software","alias":"software","description":" Computer software, or simply software, is a collection of data or computer instructions that tell the computer how to work. This is in contrast to physical hardware, from which the system is built and actually performs the work. In computer science and software engineering, computer software is all information processed by computer systems, programs, and data. Computer software includes computer programs, libraries and related non-executable data, such as online documentation or digital media. Computer hardware and software require each other and neither can be realistically used on its own.\r\nAt the lowest programming level, executable code consists of machine language instructions supported by an individual processor — typically a central processing unit (CPU) or a graphics processing unit (GPU). A machine language consists of groups of binary values signifying processor instructions that change the state of the computer from its preceding state. For example, an instruction may change the value stored in a particular storage location in the computer—an effect that is not directly observable to the user. An instruction may also invoke one of many input or output operations, for example displaying some text on a computer screen; causing state changes that should be visible to the user. The processor executes the instructions in the order they are provided, unless it is instructed to &quot;jump&quot; to a different instruction, or is interrupted by the operating system. As of 2015, most personal computers, smartphone devices, and servers have processors with multiple execution units or multiple processors performing computation together, and computing has become a much more concurrent activity than in the past.\r\nThe majority of software is written in high-level programming languages. They are easier and more efficient for programmers because they are closer to natural languages than machine languages. High-level languages are translated into machine language using a compiler or an interpreter or a combination of the two. Software may also be written in a low-level assembly language, which has strong correspondence to the computer's machine language instructions and is translated into machine language using an assembler.","materialsDescription":" <span style=\"font-weight: bold; \">What is software?</span>\r\nSometimes abbreviated as SW and S/W, software is a collection of instructions that enable the user to interact with a computer, its hardware, or perform tasks. Without software, most computers would be useless. For example, without your Internet browser software, you could not surf the Internet or read this page. Without an operating system, the browser could not run on your computer. The picture shows a Microsoft Excel box, an example of a spreadsheet software program.\r\n<span style=\"font-weight: bold; \">How do you get software?</span>\r\nSoftware can be purchased at a retail computer store or online and come in a box containing all the disks (floppy diskette, CD, DVD, or Blu-ray), manuals, warranty, and other documentation.\r\nSoftware can also be downloaded to a computer over the Internet. Once downloaded, setup files are run to start the installation process on your computer.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Free software</span></span>\r\nThere are also a lot of free software programs available that are separated into different categories.\r\n<ul><li>Shareware or trial software is software that gives you a few days to try the software before you have to buy the program. After the trial time expires, you'll be asked to enter a code or register the product before you can continue to use it.</li><li>Freeware is completely free software that never requires payment, as long as it is not modified.</li><li>Open-source software is similar to freeware. Not only is the program given away free, but the source code used to make the program is also, allowing anyone to modify the program or view how it was created.</li></ul>\r\n<span style=\"font-weight: bold; \">How do you use computer software?</span>\r\nOnce the software is installed on the computer hard drive, the program can be used anytime by finding the program on the computer. On a Windows computer, a program icon is added to the Start menu or Start screen, depending on your version of Windows.\r\n<span style=\"font-weight: bold;\">How to maintain software?</span>\r\nAfter the software is installed on your computer, it may need to be updated to fix any found errors. Updating a program can be done using software patches. Once updates are installed, any problems that may have been experienced in the program will no longer occur.\r\n<span style=\"font-weight: bold;\">How is software created and how does it work?</span>\r\nA computer programmer (or several computer programmers) writes the instructions using a programming language, defining how the software should operate on structured data. The program may then be interpreted or compiled into machine code.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Software.png"},{"id":840,"title":"ICS/SCADA Cyber Security","alias":"icsscada-cyber-security","description":"SCADA security is the practice of protecting supervisory control and data acquisition (SCADA) networks, a common framework of control systems used in industrial operations. These networks are responsible for providing automated control and remote human management of essential commodities and services such as water, natural gas, electricity and transportation to millions of people. They can also be used to improve the efficiencies and quality in other less essential (but some would say very important!) real-world processes such as snowmaking for ski resorts and beer brewing. SCADA is one of the most common types of industrial control systems (ICS).\r\nThese networks, just like any other network, are under threat from cyber-attacks that could bring down any part of the nation's critical infrastructure quickly and with dire consequences if the right security is not in place. Capital expenditure is another key concern; SCADA systems can cost an organization from tens of thousands to millions of dollars. For these reasons, it is essential that organizations implement robust SCADA security measures to protect their infrastructure and the millions of people that would be affected by the disruption caused by an external attack or internal error.\r\nSCADA security has evolved dramatically in recent years. Before computers, the only way to monitor a SCADA network was to deploy several people to each station to report back on the state of each system. In busier stations, technicians were stationed permanently to manually operate the network and communicate over telephone wires.\r\nIt wasn't until the introduction of the local area network (LAN) and improvements in system miniaturization that we started to see advances in SCADA development such as the distributed SCADA network. Next came networked systems that were able to communicate over a wide area network (WAN) and connect many more components together.\r\nFrom local companies to federal governments, every business or organization that works with SCADA systems are vulnerable to SCADA security threats. These threats can have wide-reaching effects on both the economy and the community. Specific threats to SCADA networks include the following:\r\n<span style=\"font-weight: bold;\">Hackers.</span> Individuals or groups with malicious intent could bring a SCADA network to its knees. By gaining access to key SCADA components, hackers could unleash chaos on an organization that can range from a disruption in services to cyber warfare.\r\n<span style=\"font-weight: bold;\">Malware.</span> Malware, including viruses, spyware and ransomware can pose a risk to SCADA systems. While malware may not be able to specifically target the network itself, it can still pose a threat to the key infrastructure that helps to manage the SCADA network. This includes mobile SCADA applications that are used to monitor and manage SCADA systems.\r\n<span style=\"font-weight: bold;\">Terrorists.</span> Where hackers are usually motivated by sordid gain, terrorists are driven by the desire to cause as much mayhem and damage as possible.\r\n<span style=\"font-weight: bold;\">Employees.</span> Insider threats can be just as damaging as external threats. From human error to a disgruntled employee or contractor, it is essential that SCADA security addresses these risks.\r\nManaging today's SCADA networks can be a challenge without the right security precautions in place. Many networks are still without the necessary detection and monitoring systems and this leaves them vulnerable to attack. Because SCADA network attacks exploit both cyber and physical vulnerabilities, it is critical to align cybersecurity measures accordingly.","materialsDescription":"<span style=\"font-weight: bold;\">What is the difference between ICS/SCADA cybersecurity and information security?</span>\r\nAutomated process control systems (SCADA) have a lot of differences from “traditional” corporate information systems: from the destination, specific data transfer protocols and equipment used and ending with the environment in which they operate. In corporate networks and systems, as a rule, the main protected resource is information that is processed, transmitted and stored in automated systems, and the main goal is to ensure its confidentiality. In ICS, the protected resource, first of all, is the technological process itself, and the main goal is to ensure its continuity (accessibility of all nodes) and integrity (including information transmitted between the nodes of the ICS). Moreover, the field of potential risks and threats to ICS, in comparison with corporate systems, expands with risks of potential damage to life and health of personnel and the public, damage to the environment and infrastructure. That is why it is incorrect to talk about “information security” in relation to ICS/SCADA. In English sources, the term “cybersecurity” is used for this, a direct translation of which (cybersecurity) is increasingly found in our market in relation to the protection of process control systems.\r\n<span style=\"font-weight: bold;\">Is it really necessary?</span>\r\nIt is necessary. There are a number of myths about process control systems, for example: “process control systems are completely isolated from the outside world”, “process control systems are too specific for someone to crack”, “process control systems are reliably protected by the developer”, or even “No one will ever try us, hacking us is not interesting. ” All this is no longer true. Many modern distributed process control systems have one or another connection with the corporate network, even if the system owners are unaware of this. Communication with the outside world greatly simplifies the task of the attacker, but does not remain the only possible option. Automated process control software and data transfer protocols are, as a rule, very, very insecure against cyber threats. This is evidenced by numerous articles and reports of experts involved in the study of the protection of industrial control systems and penetration tests. The PHDays III section on hacking automated process control systems impressed even ardent skeptics. Well, and, of course, the argument “they have NOT attacked us, therefore they will not” - can hardly be considered seriously. Everyone has heard about Stuxnet, which dispelled almost all the myths about the safety of ICS at once.\r\n<span style=\"font-weight: bold;\">Who needs this?</span>\r\nWith the phrase ICS/SCADA, most imagine huge plants, automated CNC machines or something similar. However, the application of process control systems is not limited to these objects - in the modern age of automation, process control systems are used everywhere: from large production facilities, the oil and gas industry, transport management to smart home systems. And, by the way, with the protection of the latter, as a rule, everything can be much worse, because the developer silently and imperceptibly shifts responsibility to the shoulders of the user.\r\nOf course, some of the objects with automated process control systems are more interesting for attackers, others less. But, given the ever-growing number of vulnerabilities discovered and published in the ICS, the spread of &quot;exclusive&quot; (written for specific protocols and ICS software) malware, considering your system safe &quot;by default&quot; is unreasonable.\r\n<span style=\"font-weight: bold;\">Are ICS and SCADA the same thing?</span>\r\nNo. SCADA systems (supervisory control and data acquisition, supervisory control and data collection) are part of the control system. Usually, a SCADA system means centralized control and management systems with the participation of a person as a whole system or a complex of industrial control systems. SCADA is the central link between people (human-machine interfaces) and PLC levels (programmable logic controller) or RTU (remote terminal unit).\r\n<span style=\"font-weight: bold;\">What is ICS/SCADA cybersecurity?</span>\r\nIn fact, ICS cybersecurity is a process similar to “information security” in a number of properties, but very different in details. And the devil, as you know, lies in them. ICS/SCADA also has similar information security-related processes: asset inventory, risk analysis and assessment, threat analysis, security management, change management, incident response, continuity, etc. But these processes themselves are different.<br />The cyber security of ICSs has the same basic target qualities - confidentiality, integrity and accessibility, but the significance and point of application for them are completely different. It should be remembered that in ICS/SCADA we, first of all, protect the technological process. Beyond this - from the risks of damage to human health and life and the environment.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_SCADA_Cyber_Security.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4716,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/F5_Networks_logo.png","logo":true,"scheme":false,"title":"F5 Big-IP Application Delivery Services","vendorVerified":0,"rating":"0.00","implementationsCount":1,"suppliersCount":0,"supplierPartnersCount":1,"alias":"f5-big-ip-application-delivery-services","companyTitle":"F5 Networks","companyTypes":["vendor"],"companyId":2749,"companyAlias":"f5-networks","description":"<span style=\"font-weight: bold;\">Explore BIG-IP application services</span>\r\nKeep your apps up and running with BIG-IP application delivery controllers. BIG-IP Local Traffic Manager (LTM) and BIG-IP DNS handle your application traffic and secure your infrastructure. You’ll get built-in security, traffic management, and performance application services, whether your applications live in a private data center or in the cloud.\r\n<span style=\"font-weight: bold;\">Service Provider</span>\r\nBIG-IP Diameter Traffic Management, BIG-IP Policy Enforcement Manager (PEM), and BIG-IP Carrier-Grade NAT (CGNAT) manage network resources to keep your applications performing at carrier-grade levels. They also help you identify ways to optimize and monetize your network, improving your bottom line.\r\n<span style=\"font-weight: bold;\">Platforms</span>\r\nGet the right platform for your business, whether you deploy your applications on-premises, in the cloud, or both. Hardware appliances include the new BIG-IP iSeries or our high-performing VIPRION chassis and blades. Software options are available through BIG-IP virtual edition or BIG-IP Cloud Edition.","shortDescription":"BIG-IP Application Delivery Services - advanced technology for an app-centric world.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":11,"sellingCount":2,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"F5 Big-IP Application Delivery Services","keywords":"","description":"<span style=\"font-weight: bold;\">Explore BIG-IP application services</span>\r\nKeep your apps up and running with BIG-IP application delivery controllers. BIG-IP Local Traffic Manager (LTM) and BIG-IP DNS handle your application traffic and secure your infrastru","og:title":"F5 Big-IP Application Delivery Services","og:description":"<span style=\"font-weight: bold;\">Explore BIG-IP application services</span>\r\nKeep your apps up and running with BIG-IP application delivery controllers. BIG-IP Local Traffic Manager (LTM) and BIG-IP DNS handle your application traffic and secure your infrastru","og:image":"https://old.roi4cio.com/fileadmin/user_upload/F5_Networks_logo.png"},"eventUrl":"","translationId":4717,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":5,"title":"Security Software","alias":"security-software","description":" Computer security software or cybersecurity software is any computer program designed to enhance information security. Security software is a broad term that encompasses a suite of different types of software that deliver data and computer and network security in various forms. \r\nSecurity software can protect a computer from viruses, malware, unauthorized users and other security exploits originating from the Internet. Different types of security software include anti-virus software, firewall software, network security software, Internet security software, malware/spamware removal and protection software, cryptographic software, and more.\r\nIn end-user computing environments, anti-spam and anti-virus security software is the most common type of software used, whereas enterprise users add a firewall and intrusion detection system on top of it. \r\nSecurity soft may be focused on preventing attacks from reaching their target, on limiting the damage attacks can cause if they reach their target and on tracking the damage that has been caused so that it can be repaired. As the nature of malicious code evolves, security software also evolves.<span style=\"font-weight: bold; \"></span>\r\n<span style=\"font-weight: bold; \">Firewall. </span>Firewall security software prevents unauthorized users from accessing a computer or network without restricting those who are authorized. Firewalls can be implemented with hardware or software. Some computer operating systems include software firewalls in the operating system itself. For example, Microsoft Windows has a built-in firewall. Routers and servers can include firewalls. There are also dedicated hardware firewalls that have no other function other than protecting a network from unauthorized access.\r\n<span style=\"font-weight: bold; \">Antivirus.</span> Antivirus solutions work to prevent malicious code from attacking a computer by recognizing the attack before it begins. But it is also designed to stop an attack in progress that could not be prevented, and to repair damage done by the attack once the attack abates. Antivirus software is useful because it addresses security issues in cases where attacks have made it past a firewall. New computer viruses appear daily, so antivirus and security software must be continuously updated to remain effective.\r\n<span style=\"font-weight: bold; \">Antispyware.</span> While antivirus software is designed to prevent malicious software from attacking, the goal of antispyware software is to prevent unauthorized software from stealing information that is on a computer or being processed through the computer. Since spyware does not need to attempt to damage data files or the operating system, it does not trigger antivirus software into action. However, antispyware software can recognize the particular actions spyware is taking by monitoring the communications between a computer and external message recipients. When communications occur that the user has not authorized, antispyware can notify the user and block further communications.\r\n<span style=\"font-weight: bold; \">Home Computers.</span> Home computers and some small businesses usually implement&nbsp; security software at the desktop level - meaning on the PC itself. This category of computer security and protection, sometimes referred to as end-point security, remains resident, or continuously operating, on the desktop. Because the software is running, it uses system resources, and can slow the computer's performance. However, because it operates in real time, it can react rapidly to attacks and seek to shut them down when they occur.\r\n<span style=\"font-weight: bold; \">Network Security.</span> When several computers are all on the same network, it's more cost-effective to implement security at the network level. Antivirus software can be installed on a server and then loaded automatically to each desktop. However firewalls are usually installed on a server or purchased as an independent device that is inserted into the network where the Internet connection comes in. All of the computers inside the network communicate unimpeded, but any data going in or out of the network over the Internet is filtered trough the firewall.<br /><br /><br />","materialsDescription":"<h1 class=\"align-center\"> <span style=\"font-weight: normal; \">What is IT security software?</span></h1>\r\nIT security software provides protection to businesses’ computer or network. It serves as a defense against unauthorized access and intrusion in such a system. It comes in various types, with many businesses and individuals already using some of them in one form or another.\r\nWith the emergence of more advanced technology, cybercriminals have also found more ways to get into the system of many organizations. Since more and more businesses are now relying their crucial operations on software products, the importance of security system software assurance must be taken seriously – now more than ever. Having reliable protection such as a security software programs is crucial to safeguard your computing environments and data. \r\n<p class=\"align-left\">It is not just the government or big corporations that become victims of cyber threats. In fact, small and medium-sized businesses have increasingly become targets of cybercrime over the past years. </p>\r\n<h1 class=\"align-center\"><span style=\"font-weight: normal; \">What are the features of IT security software?</span></h1>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Automatic updates. </span>This ensures you don’t miss any update and your system is the most up-to-date version to respond to the constantly emerging new cyber threats.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Real-time scanning.</span> Dynamic scanning features make it easier to detect and infiltrate malicious entities promptly. Without this feature, you’ll risk not being able to prevent damage to your system before it happens.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Auto-clean.</span> A feature that rids itself of viruses even without the user manually removing it from its quarantine zone upon detection. Unless you want the option to review the malware, there is no reason to keep the malicious software on your computer which makes this feature essential.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Multiple app protection.</span> This feature ensures all your apps and services are protected, whether they’re in email, instant messenger, and internet browsers, among others.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application level security.</span> This enables you to control access to the application on a per-user role or per-user basis to guarantee only the right individuals can enter the appropriate applications.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Role-based menu.</span> This displays menu options showing different users according to their roles for easier assigning of access and control.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Row-level (multi-tenant) security.</span> This gives you control over data access at a row-level for a single application. This means you can allow multiple users to access the same application but you can control the data they are authorized to view.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Single sign-on.</span> A session or user authentication process that allows users to access multiple related applications as long as they are authorized in a single session by only logging in their name and password in a single place.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">User privilege parameters.</span> These are customizable features and security as per individual user or role that can be accessed in their profile throughout every application.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application activity auditing.</span> Vital for IT departments to quickly view when a user logged in and off and which application they accessed. Developers can log end-user activity using their sign-on/signoff activities.</li></ul>\r\n<p class=\"align-left\"><br /><br /><br /><br /></p>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Software.png"},{"id":56,"title":"Router","alias":"router","description":"A router is a networking device that forwards data packets between computer networks. Routers perform the traffic directing functions on the Internet. Data sent through the internet, such as a web page or email, is in the form of data packets. A packet is typically forwarded from one router to another router through the networks that constitute an internetwork (e.g. the Internet) until it reaches its destination node.\r\nA router is connected to two or more data lines from different IP networks. When a data packet comes in on one of the lines, the router reads the network address information in the packet header to determine the ultimate destination. Then, using information in its routing table or routing policy, it directs the packet to the next network on its journey.\r\nThe most familiar type of IP routers are home and small office routers that simply forward IP packets between the home computers and the Internet. An example of a router would be the owner's cable or DSL router, which connects to the Internet through an Internet service provider (ISP). More sophisticated routers, such as enterprise routers, connect large business or ISP networks up to the powerful core routers that forward data at high speed along the optical fiber lines of the Internet backbone.\r\nThe main purpose of a router is to connect multiple networks and forward packets destined either for its own networks or other networks. A router is considered a layer-3 device because its primary forwarding decision is based on the information in the layer-3 IP packet, specifically the destination IP address. When a router receives a packet, it searches its routing table to find the best match between the destination IP address of the packet and one of the addresses in the routing table. Once a match is found, the packet is encapsulated in the layer-2 data link frame for the outgoing interface indicated in the table entry. A router typically does not look into the packet payload,[citation needed] but only at the layer-3 addresses to make a forwarding decision, plus optionally other information in the header for hints on, for example, quality of service (QoS). For pure IP forwarding, a router is designed to minimize the state information associated with individual packets. Once a packet is forwarded, the router does not retain any historical information about the packet.\r\nThe routing table itself can contain information derived from a variety of sources, such as a default or static routes that are configured manually, or dynamic routing protocols where the router learns routes from other routers. A default route is one that is used to route all traffic whose destination does not otherwise appear in the routing table; this is common – even necessary – in small networks, such as a home or small business where the default route simply sends all non-local traffic to the Internet service provider. The default route can be manually configured (as a static route), or learned by dynamic routing protocols, or be obtained by DHCP.\r\nA router can run more than one routing protocol at a time, particularly if it serves as an autonomous system border router between parts of a network that run different routing protocols; if it does so, then redistribution may be used (usually selectively) to share information between the different protocols running on the same router.\r\nBesides making a decision as to which interface a packet is forwarded to, which is handled primarily via the routing table, a router also has to manage congestion when packets arrive at a rate higher than the router can process. Three policies commonly used in the Internet are tail drop, random early detection (RED), and weighted random early detection (WRED). Tail drop is the simplest and most easily implemented; the router simply drops new incoming packets once the length of the queue exceeds the size of the buffers in the router. RED probabilistically drops datagrams early when the queue exceeds a pre-configured portion of the buffer, until a pre-determined max, when it becomes tail drop. WRED requires a weight on the average queue size to act upon when the traffic is about to exceed the pre-configured size, so that short bursts will not trigger random drops.\r\nAnother function a router performs is to decide which packet should be processed first when multiple queues exist. This is managed through QoS, which is critical when Voice over IP is deployed, so as not to introduce excessive latency.\r\nYet another function a router performs is called policy-based routing where special rules are constructed to override the rules derived from the routing table when a packet forwarding decision is made.\r\nRouter functions may be performed through the same internal paths that the packets travel inside the router. Some of the functions may be performed through an application-specific integrated circuit (ASIC) to avoid overhead of scheduling CPU time to process the packets. Others may have to be performed through the CPU as these packets need special attention that cannot be handled by an ASIC.","materialsDescription":" <span style=\"font-weight: bold;\">What Is a Router?</span>\r\nRouters are the nodes that make up a computer network like the internet. The router you use at home is the central node of your home network.\r\nIt functions as an information manager between the internet and all devices that go online (i.e. all devices connected to the router). Generally speaking, routers direct incoming traffic to its destination.\r\nThis also makes your router the first line of security in protecting your home network from malicious online attacks.\r\n<span style=\"font-weight: bold;\">What Does a Router Do?</span>\r\nYour router handles network traffic. For example, to view this article, data packages coding for this website have to transit from our server, through various nodes on the internet, and finally through your router to arrive on your phone or computer. On your device, your browser decodes those data packages to display the article you’re currently reading.\r\nSince a typical household has more than one device that connects to the internet, you need a router to manage the incoming network signals. In other words, your router makes sure that the data packages coding for a website you want to view on your computer aren’t sent to your phone. It does that by using your device’s MAC address.\r\nWhile your router has a unique (external) IP address to receive data packages from servers worldwide, every device on your home network also carries a unique MAC address. Simply put, when you try to access information online, your router maintains a table to keep track of which device requested information from where. Based on this table, your router distributes incoming data packages to the correct recipient.\r\n<span style=\"font-weight: bold;\">What Is the Difference Between Modems and Routers?</span>\r\nA modem turns the proprietary network signal of your ISP (internet service provider) into a standard network signal. In theory, you can choose between multiple ISPs and some of them may use the same delivery route. Your modem knows which signals to read and translate.\r\nThe kind of modem your ISP will provide you with depends on how you’re connecting to the internet. For example, a DSL modem requires a different technology than a cable or fiber optic broadband modem. That’s because one uses the copper wiring of your telephone line, while the others use a coaxial or a fiber optic cable, respectively.\r\nThe DSL modem has to filter and read both the low frequencies that phone and voice data produce, as well as the high frequencies of internet data. Cable modems, on the other hand, have to differentiate between television and internet signals, which are transmitted on different channels, rather than different frequencies. Finally, fiber optic uses pulses of light to transmit information. The modem has to decode these signals into standard data packages.\r\nOnce the modem has turned the ISP’s network signal into data packages, the router can distribute them to the target device.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/Router1.png"},{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3440,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/CyberGuardian.png","logo":true,"scheme":false,"title":"CyberGuardian","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"cyberguardian","companyTitle":"AlphaGuardian Networks","companyTypes":["supplier"],"companyId":5172,"companyAlias":"alphaguardian-networks","description":"You need to manage your remote IoT devices but, you must also keep them secure from cyber and physical attacks. CyberGuardian is the only product that can both monitor all operational data from your IoT systems and securely manage them as well. CyberGuardian is the perfect solution for remotely monitoring critical IoT systems including:\r\n<ul><li>Inverters</li><li>Backup Generators</li><li>Uninterruptible Power Supplies</li><li>Rectifiers</li><li>Lighting Systems</li></ul>\r\nAll of these systems communicate with legacy protocols that are vulnerable to being hacked by anyone with the will to do so.&nbsp; These protocols are listed below with links to peer-reviewed research showing their specific vulnerabilities to cyber, physical and operational attacks:\r\n<ul><li>SNMP</li><li>Modbus</li><li>BACnet</li></ul>\r\nHackers now routinely target monitoring systems that use these protocols due to the lack of security between the SNMP, Modbus and BACnet devices and the monitoring consoles.&nbsp; In order to securely monitor any system with one of these protocols, you need to go beyond open monitoring of your remote sites and, instead provide full site protection from Cyber, Physical and Operational problems.&nbsp; CyberGuardian’s patented technology provides the world’s first truly secure remote monitoring platform for your IoT devices and it provides complete protection from all threats to your site and its equipment.\r\nCyberGuardian stops hackers dead in their tracks with its integrated firewall to block ANY attempt to connect with the systems that it monitors and protects.&nbsp; In addition, as it monitors data from your critical SNMP, Modbus and BACnet-base systems, CyberGuardian uses its onboard analytics to continuously scan for any potential cyber, physical or operational anomaly.&nbsp; It regularly sends all information gathered from your systems via a Military-Grade encrypted link to our secure AlphaGuardian Cloud Server. CyberGuardian secures all IIoT systems that it monitors inside its Cyber-Safe-Envelope to provide you with fully secure monitoring capabilities from any location.","shortDescription":"CyberGuardian – secure remote IoT management.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":19,"sellingCount":15,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"CyberGuardian","keywords":"","description":"You need to manage your remote IoT devices but, you must also keep them secure from cyber and physical attacks. CyberGuardian is the only product that can both monitor all operational data from your IoT systems and securely manage them as well. CyberGuardian i","og:title":"CyberGuardian","og:description":"You need to manage your remote IoT devices but, you must also keep them secure from cyber and physical attacks. CyberGuardian is the only product that can both monitor all operational data from your IoT systems and securely manage them as well. CyberGuardian i","og:image":"https://old.roi4cio.com/fileadmin/user_upload/CyberGuardian.png"},"eventUrl":"","translationId":3441,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":5,"title":"Security Software","alias":"security-software","description":" Computer security software or cybersecurity software is any computer program designed to enhance information security. Security software is a broad term that encompasses a suite of different types of software that deliver data and computer and network security in various forms. \r\nSecurity software can protect a computer from viruses, malware, unauthorized users and other security exploits originating from the Internet. Different types of security software include anti-virus software, firewall software, network security software, Internet security software, malware/spamware removal and protection software, cryptographic software, and more.\r\nIn end-user computing environments, anti-spam and anti-virus security software is the most common type of software used, whereas enterprise users add a firewall and intrusion detection system on top of it. \r\nSecurity soft may be focused on preventing attacks from reaching their target, on limiting the damage attacks can cause if they reach their target and on tracking the damage that has been caused so that it can be repaired. As the nature of malicious code evolves, security software also evolves.<span style=\"font-weight: bold; \"></span>\r\n<span style=\"font-weight: bold; \">Firewall. </span>Firewall security software prevents unauthorized users from accessing a computer or network without restricting those who are authorized. Firewalls can be implemented with hardware or software. Some computer operating systems include software firewalls in the operating system itself. For example, Microsoft Windows has a built-in firewall. Routers and servers can include firewalls. There are also dedicated hardware firewalls that have no other function other than protecting a network from unauthorized access.\r\n<span style=\"font-weight: bold; \">Antivirus.</span> Antivirus solutions work to prevent malicious code from attacking a computer by recognizing the attack before it begins. But it is also designed to stop an attack in progress that could not be prevented, and to repair damage done by the attack once the attack abates. Antivirus software is useful because it addresses security issues in cases where attacks have made it past a firewall. New computer viruses appear daily, so antivirus and security software must be continuously updated to remain effective.\r\n<span style=\"font-weight: bold; \">Antispyware.</span> While antivirus software is designed to prevent malicious software from attacking, the goal of antispyware software is to prevent unauthorized software from stealing information that is on a computer or being processed through the computer. Since spyware does not need to attempt to damage data files or the operating system, it does not trigger antivirus software into action. However, antispyware software can recognize the particular actions spyware is taking by monitoring the communications between a computer and external message recipients. When communications occur that the user has not authorized, antispyware can notify the user and block further communications.\r\n<span style=\"font-weight: bold; \">Home Computers.</span> Home computers and some small businesses usually implement&nbsp; security software at the desktop level - meaning on the PC itself. This category of computer security and protection, sometimes referred to as end-point security, remains resident, or continuously operating, on the desktop. Because the software is running, it uses system resources, and can slow the computer's performance. However, because it operates in real time, it can react rapidly to attacks and seek to shut them down when they occur.\r\n<span style=\"font-weight: bold; \">Network Security.</span> When several computers are all on the same network, it's more cost-effective to implement security at the network level. Antivirus software can be installed on a server and then loaded automatically to each desktop. However firewalls are usually installed on a server or purchased as an independent device that is inserted into the network where the Internet connection comes in. All of the computers inside the network communicate unimpeded, but any data going in or out of the network over the Internet is filtered trough the firewall.<br /><br /><br />","materialsDescription":"<h1 class=\"align-center\"> <span style=\"font-weight: normal; \">What is IT security software?</span></h1>\r\nIT security software provides protection to businesses’ computer or network. It serves as a defense against unauthorized access and intrusion in such a system. It comes in various types, with many businesses and individuals already using some of them in one form or another.\r\nWith the emergence of more advanced technology, cybercriminals have also found more ways to get into the system of many organizations. Since more and more businesses are now relying their crucial operations on software products, the importance of security system software assurance must be taken seriously – now more than ever. Having reliable protection such as a security software programs is crucial to safeguard your computing environments and data. \r\n<p class=\"align-left\">It is not just the government or big corporations that become victims of cyber threats. In fact, small and medium-sized businesses have increasingly become targets of cybercrime over the past years. </p>\r\n<h1 class=\"align-center\"><span style=\"font-weight: normal; \">What are the features of IT security software?</span></h1>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Automatic updates. </span>This ensures you don’t miss any update and your system is the most up-to-date version to respond to the constantly emerging new cyber threats.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Real-time scanning.</span> Dynamic scanning features make it easier to detect and infiltrate malicious entities promptly. Without this feature, you’ll risk not being able to prevent damage to your system before it happens.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Auto-clean.</span> A feature that rids itself of viruses even without the user manually removing it from its quarantine zone upon detection. Unless you want the option to review the malware, there is no reason to keep the malicious software on your computer which makes this feature essential.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Multiple app protection.</span> This feature ensures all your apps and services are protected, whether they’re in email, instant messenger, and internet browsers, among others.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application level security.</span> This enables you to control access to the application on a per-user role or per-user basis to guarantee only the right individuals can enter the appropriate applications.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Role-based menu.</span> This displays menu options showing different users according to their roles for easier assigning of access and control.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Row-level (multi-tenant) security.</span> This gives you control over data access at a row-level for a single application. This means you can allow multiple users to access the same application but you can control the data they are authorized to view.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Single sign-on.</span> A session or user authentication process that allows users to access multiple related applications as long as they are authorized in a single session by only logging in their name and password in a single place.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">User privilege parameters.</span> These are customizable features and security as per individual user or role that can be accessed in their profile throughout every application.</li></ul>\r\n\r\n<ul><li><span style=\"font-weight: bold; \">Application activity auditing.</span> Vital for IT departments to quickly view when a user logged in and off and which application they accessed. Developers can log end-user activity using their sign-on/signoff activities.</li></ul>\r\n<p class=\"align-left\"><br /><br /><br /><br /></p>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Software.png"},{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3442,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/portwell-logo.jpg","logo":true,"scheme":false,"title":"Portwell's Solutions for Internet of Things (IoT)","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"portwells-solutions-for-internet-of-things-iot","companyTitle":"American Portwell Technology","companyTypes":["supplier"],"companyId":5173,"companyAlias":"american-portwell-technology","description":"Most pundits in the industry predicted that there will be more than 200 billion devices by 2020, connected to the Internet, or some would call the “cloud”. This is described as the era of the Internet of Things (IoT). The IoT is a big collection of smart sensors, networks, servers, and services that interact among them. This trend applies to all sectors or markets, and it is a way to automate, control, and manage a factory, home, transportation, energy, medical/healthcare facility, etc. All layers of networks, from applications, middleware, virtualization, connectivity, and devices, will contribute to realizing the full power of IoT. For edge connectivity, the intelligent gateways play a major role in between the devices and the cloud in building the path for, collecting data from the devices for analysis, and forwarding the instructions from the upend servers to activate the devices.\r\n<span style=\"font-weight: bold;\">Portwell's Solutions for the Internet of Things (IoT)</span>\r\nTo leverage the current internet infrastructure, an intelligent IoT gateway is developed for the purpose of connecting legacy and new equipment, from garage door opener, vending machine, cooling or heating devices to industrial robot and wind turbine, to get the data from them, and in return to control them intelligently based on the instructions or analytical results from the connected servers. Since most of the industrial automation devices are often designed in different protocols of interconnectivity. A versatile IoT gateway with various protocol supports is also used as the path between these automation devices and the cloud.\r\n<span style=\"font-weight: bold;\">Portwell IoT Gateway Solutions</span>\r\nPortwell, a world-leading innovator in Industrial PC (IPC) and a Premier member of the Intel Internet of Things (IoT) Alliance, provides a series of the off-the-shelf Intelligent IoT Gateway solutions. Furthermore, to address customers’ needs in supporting various protocols to different sensors, actuators, and devices, Portwell offers design service, including but not limited to, adding I/Os for more connectivity, customizing the chassis, fine-tuning the power source. Also, Portwell has been taken full advantage of the Intel SoC (system on chip) processors to design compact and sleek intelligent gateway devices packed with great features, such as local data or decision processing, advanced data encryption, remote security management, and in-device analytics. And the Portwell IoT gateways support software in the OS environment of customers’ choice: Linux, Microsoft® Windows® CE, and Windows.","shortDescription":"Portwell, a world-leading innovator in Industrial PC (IPC) and a Premier member of the Intel Internet of Things (IoT) Alliance, provides a series of the off-the-shelf Intelligent IoT Gateway solutions","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":16,"sellingCount":13,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Portwell's Solutions for Internet of Things (IoT)","keywords":"","description":"Most pundits in the industry predicted that there will be more than 200 billion devices by 2020, connected to the Internet, or some would call the “cloud”. This is described as the era of the Internet of Things (IoT). The IoT is a big collection of smart senso","og:title":"Portwell's Solutions for Internet of Things (IoT)","og:description":"Most pundits in the industry predicted that there will be more than 200 billion devices by 2020, connected to the Internet, or some would call the “cloud”. This is described as the era of the Internet of Things (IoT). The IoT is a big collection of smart senso","og:image":"https://old.roi4cio.com/fileadmin/user_upload/portwell-logo.jpg"},"eventUrl":"","translationId":3443,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":5259,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/lenovo_logo.png","logo":true,"scheme":false,"title":"All-in-One PC Lenovo ThinkCentre M Series","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":26,"alias":"all-in-one-pc-lenovo-thinkcentre-m-series","companyTitle":"Lenovo","companyTypes":["vendor"],"companyId":318,"companyAlias":"lenovo","description":"<span style=\"font-weight: bold; \">Productivity enhancers</span>\r\nTackle spreadsheets, multiple presentations, and photo-editing with ease. With powerful Intel Core processors, the latest DDR4 computer memory, and SSD storage options, each ThinkCentre AIO is a powerful performer. Load and transfer files at lightning speed — essential for time-critical applications that require a large memory capacity or fast storage. Get things done — quickly and easily.\r\n<span style=\"font-weight: bold; \">Adapts to you</span>\r\nVersatile stands give you the freedom to use your display at any angle with tilt, height, and swivel functionality that can adapt to a range of working styles — whether sitting at a desk, or standing to serve customers, you’ll always have the best view.\r\n<span style=\"font-weight: bold;\">ThinkCentre M920z AIO</span>\r\n<span style=\"font-weight: bold;\">ThinkCentre M820z AIO</span>\r\n\r\n","shortDescription":"Lenovo M AIO Series. With their minimal footprint, professional appearance, and enterprise-level productivity, these all-in-ones are a welcome addition to the corporate desk.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":17,"sellingCount":4,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"All-in-One PC Lenovo ThinkCentre M Series","keywords":"","description":"<span style=\"font-weight: bold; \">Productivity enhancers</span>\r\nTackle spreadsheets, multiple presentations, and photo-editing with ease. With powerful Intel Core processors, the latest DDR4 computer memory, and SSD storage options, each ThinkCentre AIO is a ","og:title":"All-in-One PC Lenovo ThinkCentre M Series","og:description":"<span style=\"font-weight: bold; \">Productivity enhancers</span>\r\nTackle spreadsheets, multiple presentations, and photo-editing with ease. With powerful Intel Core processors, the latest DDR4 computer memory, and SSD storage options, each ThinkCentre AIO is a ","og:image":"https://old.roi4cio.com/fileadmin/user_upload/lenovo_logo.png"},"eventUrl":"","translationId":5260,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":37,"title":"PC - personal computer","alias":"pc-personal-computer","description":"A personal computer (PC) is a multi-purpose computer whose size, capabilities, and price make it feasible for individual use. Personal computers are intended to be operated directly by an end user, rather than by a computer expert or technician. Unlike large costly minicomputer and mainframes, time-sharing by many people at the same time is not used with personal computers.\r\nInstitutional or corporate computer owners in the 1960s had to write their own programs to do any useful work with the machines. While personal computer users may develop their own applications, usually these systems run commercial software, free-of-charge software (&quot;freeware&quot;), which is most often proprietary, or free and open-source software, which is provided in &quot;ready-to-run&quot;, or binary, form. Software for personal computers is typically developed and distributed independently from the hardware or operating system manufacturers. Many personal computer users no longer need to write their own programs to make any use of a personal computer, although end-user programming is still feasible. This contrasts with mobile systems, where software is often only available through a manufacturer-supported channel, and end-user program development may be discouraged by lack of support by the manufacturer.\r\nSince the early 1990s, Microsoft operating systems and Intel hardware have dominated much of the personal computer market, first with MS-DOS and then with Microsoft Windows. Alternatives to Microsoft's Windows operating systems occupy a minority share of the industry. These include Apple's macOS and free and open-source Unix-like operating systems.\r\nThe advent of personal computers and the concurrent Digital Revolution have significantly affected the lives of people in all countries.\r\n&quot;PC&quot; is an initialism for &quot;personal computer&quot;. The IBM Personal Computer incorporated the designation in its model name. It is sometimes useful to distinguish personal computers of the &quot;IBM Personal Computer&quot; family from personal computers made by other manufacturers. For example, &quot;PC&quot; is used in contrast with &quot;Mac&quot;, an Apple Macintosh computer. Since none of these Apple products were mainframes or time-sharing systems, they were all &quot;personal computers&quot; and not &quot;PC&quot; (brand) computers.","materialsDescription":" <span style=\"font-weight: bold;\">What types of stationary personal computers exist?</span>\r\n<span style=\"font-weight: bold;\">Desktops</span> - refer to the type of stationary PC. From the name it is clear that these are devices that are installed and work on a table and are not transferred during operation. As a rule, representatives of this group are high-performance powerful devices. They consist of a system unit (a rectangular box), to which a monitor, keyboard and mouse are connected.\r\n<span style=\"font-weight: bold;\">Servers</span> - this type of computer has its own specific tasks that it performs remotely or locally in place. The vast majority of servers are quite powerful machines. The appearance of the servers is slightly different from the usual PC - they are mounted in metal racks that look like furniture shelves. The racks themselves are placed in a special room (server room), the necessary temperature regime is necessarily maintained in it.\r\n<span style=\"font-weight: bold;\">Nettops</span> - refer to the type of stationary PC. The system unit is compact in size, usually with low power consumption and noise. Due to the small size, nettops have lower performance, but they fit perfectly into the home environment and do not occupy expensive office space.\r\n<span style=\"font-weight: bold;\">Microcomputers</span> are computers that fit in a miniature enclosure that looks very similar to a flash drive. The microcomputer itself does not have an output device, therefore, through an HDMI connection, it connects to a monitor or TV. Controls, such as a mouse or keyboard, are connected via the built-in USB ports or Bluetooth. Technical specifications depend on the configuration, as with any other PC.\r\n<span style=\"font-weight: bold;\">Monoblocks</span> - refer to the type of stationary PC. The system unit and the monitor are a single unit. Accessories and boards are placed in the compartment, which is mounted on the back of the monitor. It has an aesthetic appearance and does not take up much space.\r\n<span style=\"font-weight: bold;\">What are the types of portable personal computers?</span>\r\nA laptop computer can also be called portable. They differ from desktop dimensions and weight in a smaller direction and more capacious batteries, which is understandable because you need to carry it with you.\r\n<span style=\"font-weight: bold;\">Laptops and netbooks</span> - refer to the type of portable (laptop) PCs, have a battery for offline operation without using a network. The case is made in the form of a clamshell, a screen is installed at the top, and a keyboard at the bottom. Netbooks are smaller than laptops, respectively, have lower performance, although the battery life is longer.\r\n<span style=\"font-weight: bold;\">Tablet laptops</span> - refer to the type of portable (laptop) PC. The case consists of a touch screen display - Touchscreen. Their main purpose is surfing the Internet, watching videos, listening to audio, gaming and other applications. The compact dimensions make this group especially popular for travelers. Tablet laptops have a keyboard that either folds up or extends out of a niche under the screen. In tablets, the touchscreen is the input medium. For this group, battery life is important.\r\n<span style=\"font-weight: bold;\">Pocket PCs and smartphones</span> - belong to the type of portable (laptop) PC. Distinctive features are a small size and a large reserve of battery life. The input tool is either a touch screen or a retractable keyboard.","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_PC.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3474,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/BlackRidge_Technology_logo.png","logo":true,"scheme":false,"title":"BlackRidge TAC Gateways and Endpoints","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"blackridge-tac-gateways-and-endpoints","companyTitle":"BlackRidge Technology","companyTypes":["supplier","vendor"],"companyId":5185,"companyAlias":"blackridge-technology","description":"BlackRidge products include hardware and software gateways and software endpoints that implement BlackRidge Transport Access Control (TAC) with First Packet Authentication. BlackRidge gateways and endpoints perform identity insertion, identity resolution and policy enforcement on network sessions. Identity insertion is the process that associates a network connection request with a user or device identity and inserts identity tokens into TCP sessions. Identity resolution is the reverse process by which a BlackRidge gateway or endpoint associates and authenticates an identity token with a user or device identity. Policy enforcement implements the provisioned security policy — forward, redirect, or discard — for the connection request to a protected resource.\r\nA BlackRidge gateway can work in both identity insertion and identity enforcement modes and provide identity insertion on behalf of devices and users.\r\n<span style=\"font-weight: bold;\">Cloud and Virtual Gateways</span>\r\nBlackRidge gateways are available for most hypervisors and cloud to computing environments. Like their physical brethren, each appliance is configured with two data ports, along with a dedicated management port. All virtual appliances adapt to their environment, automatically sizing based on the provisioned host resources. Supported environments include VMware ESXi, Linux Kernel Virtual Machine (KVM), Amazon Web Services (AWS), and z/VM for the IBM Z.\r\n<span style=\"font-weight: bold;\">Enterprise and Branch Gateways</span>\r\nBlackRidge enterprise gateways are software that runs on 1U rack-mountable appliances in either 1GbE or 10GbE network configurations. Each gateway is configured with either two 1GbE or two 10GbE data ports, along with a 1GbE dedicated management port. Numerous network interface options are available: copper interfaces with RJ-45 or fiber optics with SFP+, SR or LR transceivers, and with optional NIC bypass capability to fail open or closed. The 1GbE gateways support up to 10,000 unique identities and 1,000,000 concurrent network sessions. The 10GbE gateways support up to 40,000 identities and 4,000,000 sessions.\r\nA fanless branch or desktop gateway is available for protecting assets in remote or branch offices, small subnets or single servers. The small form factor branch gateway is configured with two 1GbE data ports along with one 1GbE port for management, and it supports up to 1,000 identities and 100,000 concurrent network sessions.\r\n<span style=\"font-weight: bold;\">TAC Endpoints - Software, Hardware and IoT Devices</span>\r\nA BlackRidge endpoint is TAC software that is integrated into a user device or is embedded in a hardware device. The TAC endpoint performs identity insertion into TCP/IP session establishment requests and performs mutual authentication of network sessions. TAC software endpoints are available for Windows 7/10 and Ubuntu, with additional Linux operating systems and macOS to be supported.&nbsp; BlackRidge hardware endpoints include the BlackRidge TAC Identity Device and partner IoT devices.","shortDescription":"BlackRidge secures IIoT devices and OT networks via its patented First Packet Authentication technology, which authenticates identity.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":5,"sellingCount":1,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"BlackRidge TAC Gateways and Endpoints","keywords":"","description":"BlackRidge products include hardware and software gateways and software endpoints that implement BlackRidge Transport Access Control (TAC) with First Packet Authentication. BlackRidge gateways and endpoints perform identity insertion, identity resolution and p","og:title":"BlackRidge TAC Gateways and Endpoints","og:description":"BlackRidge products include hardware and software gateways and software endpoints that implement BlackRidge Transport Access Control (TAC) with First Packet Authentication. BlackRidge gateways and endpoints perform identity insertion, identity resolution and p","og:image":"https://old.roi4cio.com/fileadmin/user_upload/BlackRidge_Technology_logo.png"},"eventUrl":"","translationId":3475,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"id":178,"title":"IoT - Internet of Things","alias":"iot-internet-of-things","description":"The Internet of things (IoT) is the extension of Internet connectivity into physical devices and everyday objects. Embedded with electronics, Internet connectivity, and other forms of hardware (such as sensors), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.\r\nThe definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time analytics, machine learning, commodity sensors, and embedded systems. Traditional fields of embedded systems, wireless sensor networks, control systems, automation (including home and building automation). and others all contribute to enabling the Internet of things. In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the &quot;smart home&quot;, covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as smartphones and smart speakers.\r\nThe IoT concept has faced prominent criticism, especially in regards to privacy and security concerns related to these devices and their intention of pervasive presence.","materialsDescription":"<span style=\"font-weight: bold;\">What is the Internet of Things (IoT)?</span>\r\nThe Internet of things refers to the network of things (physical objects) that can be connected to the Internet to collect and share data without human-to-human or human-to-computer interaction.\r\n<span style=\"font-weight: bold;\">Why is it called the Internet of Things?</span>\r\nThe term Internet of things was coined by Kevin Ashton in 1999. Stemming from Kevin Ashton’s experience with RFID, the term Internet of things originally described the concept of tagging every object in a person’s life with machine-readable codes. This would allow computers to easily manage and inventory all of these things.\r\nThe term IoT today has evolved to a much broader prospect. It now encompasses ubiquitous connectivity, devices, sensors, analytics, machine learning, and many other technologies.\r\n<span style=\"font-weight: bold;\">What is an IoT solution?</span>\r\nAn IoT solution is a combination of devices or other data sources, outfitted with sensors and Internet connected hardware to securely report information back to an IoT platform. This information is often a physical metric which can help users answer a question or solve a specific problem.\r\n<span style=\"font-weight: bold;\">What is an IoT Proof of Concept (PoC)?</span>\r\nThe purpose of a PoC is to experiment with a solution in your environment, collect data, and evaluate performance from a set timeline on a set budget. A PoC is a low-risk way to introduce IoT to an organization.\r\n<span style=\"font-weight: bold;\">What is an IoT cloud platform?</span>\r\nAn IoT platform provides users with one or more of these key elements — visualization tools, data security features, a workflow engine and a custom user interface to utilize the information collected from devices and other data sources in the field. These platforms are based in the cloud and can be accessed from anywhere.\r\n<span style=\"font-weight: bold;\">What is industrial equipment monitoring?</span>\r\nIndustrial equipment monitoring uses a network of connected sensors - either native to a piece of equipment or retrofitted - to inform owners/operators of a machine’s output, component conditions, need for service or impending failure. Industrial equipment monitoring is an IoT solution which can utilize an IoT platform to unify disparate data and enable decision-makers to respond to real-time data.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/IoT_-_Internet_of_Things.png"},{"id":471,"title":"Hardware","alias":"hardware","description":" Computer hardware includes the physical, tangible parts or components of a computer, such as the cabinet, central processing unit, monitor, keyboard, computer data storage, graphics card, sound card, speakers and motherboard. By contrast, software is instructions that can be stored and run by hardware. Hardware is so-termed because it is &quot;hard&quot; or rigid with respect to changes or modifications; whereas software is &quot;soft&quot; because it is easy to update or change. Intermediate between software and hardware is &quot;firmware&quot;, which is software that is strongly coupled to the particular hardware of a computer system and thus the most difficult to change but also among the most stable with respect to consistency of interface. The progression from levels of &quot;hardness&quot; to &quot;softness&quot; in computer systems parallels a progression of layers of abstraction in computing.\r\nHardware is typically directed by the software to execute any command or instruction. A combination of hardware and software forms a usable computing system, although other systems exist with only hardware components.\r\nThe template for all modern computers is the Von Neumann architecture, detailed in a 1945 paper by Hungarian mathematician John von Neumann. This describes a design architecture for an electronic digital computer with subdivisions of a processing unit consisting of an arithmetic logic unit and processor registers, a control unit containing an instruction register and program counter, a memory to store both data and instructions, external mass storage, and input and output mechanisms. The meaning of the term has evolved to mean a stored-program computer in which an instruction fetch and a data operation cannot occur at the same time because they share a common bus. This is referred to as the Von Neumann bottleneck and often limits the performance of the system.","materialsDescription":" <span style=\"font-weight: bold; \">What does Hardware (H/W) mean?</span>\r\nHardware (H/W), in the context of technology, refers to the physical elements that make up a computer or electronic system and everything else involved that is physically tangible. This includes the monitor, hard drive, memory and CPU. Hardware works hand-in-hand with firmware and software to make a computer function.\r\n<span style=\"font-weight: bold; \">What are the types of computer systems?</span>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Personal computer</span></span>\r\nThe personal computer, also known as the PC, is one of the most common types of computer due to its versatility and relatively low price. Laptops are generally very similar, although they may use lower-power or reduced size components, thus lower performance.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Case</span></span>\r\nThe computer case encloses and holds most of the components of the system. It provides mechanical support and protection for internal elements such as the motherboard, disk drives, and power supplies, and controls and directs the flow of cooling air over internal components. The case is also part of the system to control electromagnetic interference radiated by the computer, and protects internal parts from electrostatic discharge. Large tower cases provide extra internal space for multiple disk drives or other peripherals and usually stand on the floor, while desktop cases provide less expansion room. All-in-one style designs include a video display built into the same case. Portable and laptop computers require cases that provide impact protection for the unit. A current development in laptop computers is a detachable keyboard, which allows the system to be configured as a touch-screen tablet. Hobbyists may decorate the cases with colored lights, paint, or other features, in an activity called case modding.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Power supply</span></span>\r\nA power supply unit (PSU) converts alternating current (AC) electric power to low-voltage direct current (DC) power for the internal components of the computer. Laptops are capable of running from a built-in battery, normally for a period of hours. The PSU typically uses a switched-mode power supply (SMPS), with power MOSFETs (power metal–oxide–semiconductor field-effect transistors) used in the converters and regulator circuits of the SMPS.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Motherboard</span></span>\r\nThe motherboard is the main component of a computer. It is a board with integrated circuitry that connects the other parts of the computer including the CPU, the RAM, the disk drives (CD, DVD, hard disk, or any others) as well as any peripherals connected via the ports or the expansion slots. The integrated circuit (IC) chips in a computer typically contain billions of tiny metal–oxide–semiconductor field-effect transistors (MOSFETs).\r\nComponents directly attached to or to part of the motherboard include:\r\n<ul><li><span style=\"font-weight: bold; \">The CPU (central processing unit)</span>, which performs most of the calculations which enable a computer to function, and is referred to as the brain of the computer which get a hold of program instruction from random-access memory (RAM), interprets and processes it and then send it backs to computer result so that the relevant components can carry out the instructions. The CPU is a microprocessor, which is fabricated on a metal–oxide–semiconductor (MOS) integrated circuit (IC) chip. It is usually cooled by a heat sink and fan, or water-cooling system. Most newer CPU include an on-die graphics processing unit (GPU). The clock speed of CPU governs how fast it executes instructions, and is measured in GHz; typical values lie between 1 GHz and 5 GHz. Many modern computers have the option to overclock the CPU which enhances performance at the expense of greater thermal output and thus a need for improved cooling.</li><li><span style=\"font-weight: bold; \">The chipset</span>, which includes the north bridge, mediates communication between the CPU and the other components of the system, including main memory; as well as south bridge, which is connected to the north bridge, and supports auxiliary interfaces and buses; and, finally, a Super I/O chip, connected through the south bridge, which supports the slowest and most legacy components like serial ports, hardware monitoring and fan control.</li><li><span style=\"font-weight: bold; \">Random-access memory (RAM)</span>, which stores the code and data that are being actively accessed by the CPU. For example, when a web browser is opened on the computer it takes up memory; this is stored in the RAM until the web browser is closed. It is typically a type of dynamic RAM (DRAM), such as synchronous DRAM (SDRAM), where MOS memory chips store data on memory cells consisting of MOSFETs and MOS capacitors. RAM usually comes on dual in-line memory modules (DIMMs) in the sizes of 2GB, 4GB, and 8GB, but can be much larger.</li><li><span style=\"font-weight: bold; \">Read-only memory (ROM)</span>, which stores the BIOS that runs when the computer is powered on or otherwise begins execution, a process known as Bootstrapping, or &quot;booting&quot; or &quot;booting up&quot;. The ROM is typically a nonvolatile BIOS memory chip, which stores data on floating-gate MOSFET memory cells.</li><li><span style=\"font-weight: bold; \">The BIOS (Basic Input Output System)</span> includes boot firmware and power management firmware. Newer motherboards use Unified Extensible Firmware Interface (UEFI) instead of BIOS.</li><li><span style=\"font-weight: bold; \">Buses</span> that connect the CPU to various internal components and to expand cards for graphics and sound.</li><li><span style=\"font-weight: bold; \">The CMOS</span> (complementary MOS) battery, which powers the CMOS memory for date and time in the BIOS chip. This battery is generally a watch battery.</li><li><span style=\"font-weight: bold; \">The video card</span> (also known as the graphics card), which processes computer graphics. More powerful graphics cards are better suited to handle strenuous tasks, such as playing intensive video games or running computer graphics software. A video card contains a graphics processing unit (GPU) and video memory (typically a type of SDRAM), both fabricated on MOS integrated circuit (MOS IC) chips.</li><li><span style=\"font-weight: bold; \">Power MOSFETs</span> make up the voltage regulator module (VRM), which controls how much voltage other hardware components receive.</li></ul>\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Expansion cards</span></span>\r\nAn expansion card in computing is a printed circuit board that can be inserted into an expansion slot of a computer motherboard or backplane to add functionality to a computer system via the expansion bus. Expansion cards can be used to obtain or expand on features not offered by the motherboard.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Storage devices</span></span>\r\nA storage device is any computing hardware and digital media that is used for storing, porting and extracting data files and objects. It can hold and store information both temporarily and permanently, and can be internal or external to a computer, server or any similar computing device. Data storage is a core function and fundamental component of computers.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Fixed media</span></span>\r\nData is stored by a computer using a variety of media. Hard disk drives (HDDs) are found in virtually all older computers, due to their high capacity and low cost, but solid-state drives (SSDs) are faster and more power efficient, although currently more expensive than hard drives in terms of dollar per gigabyte, so are often found in personal computers built post-2007. SSDs use flash memory, which stores data on MOS memory chips consisting of floating-gate MOSFET memory cells. Some systems may use a disk array controller for greater performance or reliability.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Removable media</span></span>\r\nTo transfer data between computers, an external flash memory device (such as a memory card or USB flash drive) or optical disc (such as a CD-ROM, DVD-ROM or BD-ROM) may be used. Their usefulness depends on being readable by other systems; the majority of machines have an optical disk drive (ODD), and virtually all have at least one Universal Serial Bus (USB) port.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input and output peripherals</span></span>\r\nInput and output devices are typically housed externally to the main computer chassis. The following are either standard or very common to many computer systems.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Input</span></span>\r\nInput devices allow the user to enter information into the system, or control its operation. Most personal computers have a mouse and keyboard, but laptop systems typically use a touchpad instead of a mouse. Other input devices include webcams, microphones, joysticks, and image scanners.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Output device</span></span>\r\nOutput devices display information in a human readable form. Such devices could include printers, speakers, monitors or a Braille embosser.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Mainframe computer</span></span>\r\nA mainframe computer is a much larger computer that typically fills a room and may cost many hundreds or thousands of times as much as a personal computer. They are designed to perform large numbers of calculations for governments and large enterprises.\r\n<span style=\"font-style: italic; \"><span style=\"font-weight: bold; \">Departmental computing</span></span>\r\nIn the 1960s and 1970s, more and more departments started to use cheaper and dedicated systems for specific purposes like process control and laboratory automation.\r\n<span style=\"font-style: italic;\"><span style=\"font-weight: bold;\">Supercomputer</span></span>\r\nA supercomputer is superficially similar to a mainframe, but is instead intended for extremely demanding computational tasks. As of June 2018, the fastest supercomputer on the TOP500supercomputer list is the Summit, in the United States, with a LINPACK benchmarkscore of 122.3 PFLOPS Light, by around 29 PFLOPS.\r\nThe term supercomputer does not refer to a specific technology. Rather it indicates the fastest computations available at any given time. In mid 2011, the fastest supercomputers boasted speeds exceeding one petaflop, or 1 quadrillion (10^15 or 1,000 trillion) floating point operations per second. Supercomputers are fast but extremely costly, so they are generally used by large organizations to execute computationally demanding tasks involving large data sets. Supercomputers typically run military and scientific applications. Although costly, they are also being used for commercial applications where huge amounts of data must be analyzed. For example, large banks employ supercomputers to calculate the risks and returns of various investment strategies, and healthcare organizations use them to analyze giant databases of patient data to determine optimal treatments for various diseases and problems incurring to the country. ","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Hardware.jpg"},{"id":540,"title":"Security Hardware","alias":"security-hardware","description":"Hardware security as a discipline originated out of cryptographic engineering and involves hardware design, access control, secure multi-party computation, secure key storage, ensuring code authenticity and measures to ensure that the supply chain that built the product is secure, among other things.\r\nA hardware security module (HSM) is a physical computing device that safeguards and manages digital keys for strong authentication and provides cryptoprocessing. These modules traditionally come in the form of a plug-in card or an external device that attaches directly to a computer or network server.\r\nSome providers in this discipline consider that the key difference between hardware security and software security is that hardware security is implemented using &quot;non-Turing-machine&quot; logic (raw combinatorial logic or simple state machines). One approach, referred to as &quot;hardsec&quot;, uses FPGAs to implement non-Turing-machine security controls as a way of combining the security of hardware with the flexibility of software.\r\nHardware backdoors are backdoors in hardware. Conceptionally related, a hardware Trojan (HT) is a malicious modification of an electronic system, particularly in the context of an integrated circuit.\r\nA physical unclonable function (PUF) is a physical entity that is embodied in a physical structure and is easy to evaluate but hard to predict. Further, an individual PUF device must be easy to make but practically impossible to duplicate, even given the exact manufacturing process that produced it. In this respect, it is the hardware analog of a one-way function. The name &quot;physically unclonable function&quot; might be a little misleading as some PUFs are clonable, and most PUFs are noisy and therefore do not achieve the requirements for a function. Today, PUFs are usually implemented in integrated circuits and are typically used in applications with high-security requirements.\r\nMany attacks on sensitive data and resources reported by organizations occur from within the organization itself.","materialsDescription":"<span style=\"font-weight: bold;\">What is hardware information security?</span>\r\nHardware means various types of devices (mechanical, electromechanical, electronic, etc.), which solve information protection problems with hardware. They impede access to information, including through its disguise. The hardware includes: noise generators, surge protectors, scanning radios and many other devices that &quot;block&quot; potential channels of information leakage or allow them to be detected. The advantages of technical means are related to their reliability, independence from subjective factors and high resistance to modification. The weaknesses include a lack of flexibility, relatively large volume and mass and high cost. The hardware for information protection includes the most diverse technical structures in terms of operation, device and capabilities, which ensure the suppression of disclosure, protection against leakage and counteraction to unauthorized access to sources of confidential information.\r\n<span style=\"font-weight: bold;\">Where is the hardware used to protect information?</span>\r\nHardware information protection is used to solve the following problems:\r\n<ul><li>conducting special studies of technical means of ensuring production activity for the presence of possible channels of information leakage;</li><li>identification of information leakage channels at various objects and in premises;</li><li>localization of information leakage channels;</li><li>search and detection of industrial espionage tools;</li><li>countering unauthorized access to confidential information sources and other actions.</li></ul>\r\n<span style=\"font-weight: bold;\">What is the classification of information security hardware?</span>\r\nAccording to the functional purpose, the hardware can be classified into detection tools, search tools and detailed measurements and active and passive countermeasures. At the same time, according to their technical capabilities, information protection tools can be general-purpose, designed for use by non-professionals in order to obtain preliminary (general) estimates, and professional complexes that allow for a thorough search, detection and precision measurement of all the characteristics of industrial espionage equipment. As an example of the former, we can consider a group of IP electromagnetic radiation indicators, which have a wide range of received signals and rather low sensitivity. As a second example - a complex for the detection and direction finding of radio bookmarks, designed to automatically detect and locate radio transmitters, radio microphones, telephone bookmarks and network radio transmitters.<br /><br />","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/icon_Security_Hardware.png"},{"id":834,"title":"IoT - Internet of Things Security","alias":"iot-internet-of-things-security","description":" IoT security is the technology area concerned with safeguarding connected devices and networks in the internet of things (IoT).\r\nIoT involves adding internet connectivity to a system of interrelated computing devices, mechanical and digital machines, objects, animals and/or people. Each &quot;thing&quot; is provided a unique identifier and the ability to automatically transfer data over a network. Allowing devices to connect to the internet opens them up to a number of serious vulnerabilities if they are not properly protected.\r\nIoT security has become the subject of scrutiny after a number of high-profile incidents where a common IoT device was used to infiltrate and attack the larger network. Implementing security measures is critical to ensuring the safety of networks with IoT devices connected to them.\r\nIoT security hacks can happen in any industry, from smart home to a manufacturing plant to a connected car. The severity of impact depends greatly on the individual system, the data collected and/or the information it contains.\r\nAn attack disabling the brakes of a connected car, for example, or on a connected health device, such as an insulin pump hacked to administer too much medication to a patient, can be life-threatening. Likewise, an attack on a refrigeration system housing medicine that is monitored by an IoT system can ruin the viability of a medicine if temperatures fluctuate. Similarly, an attack on critical infrastructure -- an oil well, energy grid or water supply -- can be disastrous.\r\nSo, a robust IoT security portfolio must allow protecting devices from all types of vulnerabilities while deploying the security level that best matches application needs. Cryptography technologies are used to combat communication attacks. Security services are offered for protecting against lifecycle attacks. Isolation measures can be implemented to fend off software attacks. And, finally, IoT security should include tamper mitigation and side-channel attack mitigation technologies for fighting physical attacks of the chip.","materialsDescription":" <span style=\"font-weight: bold;\">What are the key requirements of IoT Security?</span>\r\nThe key requirements for any IoT security solution are:\r\n<ul><li>Device and data security, including authentication of devices and confidentiality and integrity of data</li><li>Implementing and running security operations at IoT scale</li><li>Meeting compliance requirements and requests</li><li>Meeting performance requirements as per the use case</li></ul>\r\n<span style=\"font-weight: bold;\">What do connected devices require to participate in the IoT Securely?</span>\r\nTo securely participate in the IoT, each connected device needs a unique identification – even before it has an IP address. This digital credential establishes the root of trust for the device’s entire lifecycle, from initial design to deployment to retirement.\r\n<span style=\"font-weight: bold;\">Why is device authentication necessary for the IoT?</span>\r\nStrong IoT device authentication is required to ensure connected devices on the IoT can be trusted to be what they purport to be. Consequently, each IoT device needs a unique identity that can be authenticated when the device attempts to connect to a gateway or central server. With this unique ID in place, IT system administrators can track each device throughout its lifecycle, communicate securely with it, and prevent it from executing harmful processes. If a device exhibits unexpected behavior, administrators can simply revoke its privileges.\r\n<span style=\"font-weight: bold;\">Why is secure manufacturing necessary for IoT devices?</span>\r\nIoT devices produced through unsecured manufacturing processes provide criminals opportunities to change production runs to introduce unauthorized code or produce additional units that are subsequently sold on the black market.\r\nOne way to secure manufacturing processes is to use hardware security modules (HSMs) and supporting security software to inject cryptographic keys and digital certificates and to control the number of units built and the code incorporated into each.\r\n<span style=\"font-weight: bold;\">Why is code signing necessary for IoT devices?</span>\r\nTo protect businesses, brands, partners, and users from software that has been infected by malware, software developers have adopted code signing. In the IoT, code signing in the software release process ensures the integrity of IoT device software and firmware updates and defends against the risks associated with code tampering or code that deviates from organizational policies.\r\nIn public key cryptography, code signing is a specific use of certificate-based digital signatures that enables an organization to verify the identity of the software publisher and certify the software has not been changed since it was published.\r\n<span style=\"font-weight: bold;\">What is IoT PKI?</span>\r\nToday there are more things (devices) online than there are people on the planet! Devices are the number one users of the Internet and need digital identities for secure operation. As enterprises seek to transform their business models to stay competitive, rapid adoption of IoT technologies is creating increasing demand for Public Key Infrastructures (PKIs) to provide digital certificates for the growing number of devices and the software and firmware they run.\r\nSafe IoT deployments require not only trusting the devices to be authentic and to be who they say they are, but also trusting that the data they collect is real and not altered. If one cannot trust the IoT devices and the data, there is no point in collecting, running analytics, and executing decisions based on the information collected.\r\nSecure adoption of IoT requires:\r\n<ul><li>Enabling mutual authentication between connected devices and applications</li><li>Maintaining the integrity and confidentiality of the data collected by devices</li><li>Ensuring the legitimacy and integrity of the software downloaded to devices</li><li>Preserving the privacy of sensitive data in light of stricter security regulations</li></ul>","iconURL":"https://old.roi4cio.com/fileadmin/user_upload/iot.png"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]}],"jobRoles":[{"id":58,"title":"Chief Executive Officer"},{"id":60,"title":"Chief Information Officer"},{"id":62,"title":"Chief Technical Officer"},{"id":76,"title":"Technical Management"}],"organizationalFeatures":["Internet access is available for employees","Backup data center","Own Data Center"],"complementaryCategories":[],"solutions":["Aging IT infrastructure","Low quality of customer service","Low bandwidth data channels","Separate communications channels","High costs"],"materials":[{"id":1690,"title":"","description":"Dell EMC Connectrix Switches","uri":"https://shop.dellemc.com/uk-ua/Connectrix-Products/Dell-EMC-Connectrix-Switches/p/EMC-Connectrix-Switches?PID=EMC_SRS-CNNTRXS-DE7C_SPLSH"}],"useCases":[],"best_practices":[],"values":["Reduce Costs","Improve Customer Service"],"implementations":[{"id":888,"title":"Server equipment for centralization of ASBO FOBOS","url":"https://old.roi4cio.com/vnedrenija/vnedrenie/server-equipment-for-centralization-of-asbo-fobos/"}],"presenterCodeLng":"","productImplementations":[{"id":888,"title":"Server equipment for centralization of ASBO FOBOS","description":"Description is not ready yet","alias":"server-equipment-for-centralization-of-asbo-fobos","roi":0,"seo":{"title":"Server equipment for centralization of ASBO FOBOS","keywords":"","description":"Description is not ready yet","og:title":"Server equipment for centralization of ASBO FOBOS","og:description":"Description is not ready yet"},"deal_info":"","user":{"id":584,"title":"Ukrainian Railways","logoURL":"https://old.roi4cio.com/uploads/roi/company/Ukrainian_Railways_Logo.jpg","alias":"ukrzaliznycja-gosudarstvennaja-administracija-zheleznodorozhnogo-transporta-ukrainy","address":"","roles":[],"description":"Ukraine has a developed railway network, its total working mileage amounts to over 22 000 kilometers. 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By leveraging VMware software to address business challenges such as increasing resource efficiency and availability, customers have achieved significant value. - In particular, to reduce the total cost of ownership, increase the return on investment and improve the quolity of customer service.<br /><br />VMware is headquartered in Palo Alto, California, USA and is majority owned by Dell EMC.</span>","companyTypes":[],"products":{},"vendoredProductsCount":24,"suppliedProductsCount":32,"supplierImplementations":[],"vendorImplementations":[],"userImplementations":[],"userImplementationsCount":0,"supplierImplementationsCount":0,"vendorImplementationsCount":14,"vendorPartnersCount":2,"supplierPartnersCount":97,"b4r":0,"categories":{},"companyUrl":"https://www.vmware.com/","countryCodes":[],"certifications":[],"isSeller":false,"isSupplier":false,"isVendor":false,"presenterCodeLng":"","seo":{"title":"VMware","keywords":"VMware, business, with, approach, cloud, modern, data, apps","description":"<span style=\"color: rgb(97, 97, 97); \">VMware was founded in 1998 and initially focused on the development of virtual machine technologies for standard computers. 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