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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"}],"characteristics":[],"concurentProducts":[{"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. 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 & 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":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 "thing" 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"},{"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 "non-Turing-machine" logic (raw combinatorial logic or simple state machines). One approach, referred to as "hardsec", 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 "physically unclonable function" 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 "block" 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":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 "hard" or rigid with respect to changes or modifications; whereas software is "soft" because it is easy to update or change. Intermediate between software and hardware is "firmware", 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 "hardness" to "softness" 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 "booting" or "booting up". 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 "intellectual" 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":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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":4714,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/eurotech-logo.png","logo":true,"scheme":false,"title":"Eurotech Everyware IoT","vendorVerified":0,"rating":"0.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"eurotech-everyware-iot","companyTitle":"Eurotech","companyTypes":["supplier","vendor"],"companyId":5222,"companyAlias":"eurotech","description":"Eurotech provides hardware and software IoT solutions under the brand name of <span style=\"font-weight: bold;\">Everyware IoT</span>. Everyware IoT is an integrated platform for the Internet of Things that provides IoT gateways for any industry vertical, an open edge framework and modular cloud infrastructure to connect field devices to business analytics and enterprise applications. Based on open source and standards, Everyware IoT accelerates IoT application development and project deployment while avoiding vendor lock-in.\r\n<span style=\"font-weight: bold;\">Open</span>\r\nOpen-sourced, based on open standards, and supported by a large eco-system of partners, it ensures flexibility and interoperability while avoiding the limitations of proprietary and lock-in solutions.\r\n<span style=\"font-weight: bold;\">Integrated</span>\r\nEverything needed to bootstrap IoT applications for faster deployment and time to revenue. IoT edge gateways, field protocols, edge computing frameworks, and the IoT integration hub are provided in an integrated yet modular offering.\r\n<span style=\"font-weight: bold;\">Managed</span>\r\nDevOps for the IoT. Manage your field devices and your deployment. Integrated Information Technology (IT) and Operations Technology (OT) leads to increased operational efficiency, deployment flexibility and infrastructure security.\r\n\r\n<span style=\"font-weight: bold;\">Multi-service IoT Edge Gateways</span>\r\nEurotech Multi-service IoT Edge Gateways are a family of intelligent devices that offer a wide range of performance, networking and ruggedness options in order to best fit today’s IoT applications. Eurotech Multi-service IoT Edge Gateways come certified for various industry verticals including Industrial, Automotive, and Railway and are globally certified for cellular connectivity.\r\n<span style=\"font-weight: bold;\">IoT Edge Framework</span>\r\nEurotech enterprise-ready IoT Edge Framework based on Java, Everyware Software Framework (ESF), supports ready-to-use field protocols (Modbus, OPC-UA, S7), MQTT connectivity, and web-based visual data flow programming to publish data to IoT Cloud Platforms.\r\n<span style=\"font-weight: bold;\">IoT Integration Platform</span>\r\nEveryware Cloud (EC) offers an open and modular IoT Integration Platform based on a micro-services architecture. EC provides device management, diagnostics, provisioning, remote access of IoT gateways and devices, and integration services for telemetry data.","shortDescription":"Everyware IoT is an integrated platform that provides IoT gateways for any industry vertical, an open edge framework and modular cloud infrastructure to connect field devices to business analytics.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":6,"sellingCount":19,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Eurotech Everyware IoT","keywords":"","description":"Eurotech provides hardware and software IoT solutions under the brand name of <span style=\"font-weight: bold;\">Everyware IoT</span>. Everyware IoT is an integrated platform for the Internet of Things that provides IoT gateways for any industry vertical, an ope","og:title":"Eurotech Everyware IoT","og:description":"Eurotech provides hardware and software IoT solutions under the brand name of <span style=\"font-weight: bold;\">Everyware IoT</span>. Everyware IoT is an integrated platform for the Internet of Things that provides IoT gateways for any industry vertical, an ope","og:image":"https://old.roi4cio.com/fileadmin/user_upload/eurotech-logo.png"},"eventUrl":"","translationId":4715,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[],"testingArea":"","categories":[{"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 "thing" 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"},{"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 "smart home", 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":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 "non-Turing-machine" logic (raw combinatorial logic or simple state machines). One approach, referred to as "hardsec", 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 "physically unclonable function" 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 "block" 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":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"}],"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 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":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 "thing" 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"},{"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 "smart home", 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":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":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 "non-Turing-machine" logic (raw combinatorial logic or simple state machines). One approach, referred to as "hardsec", 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 "physically unclonable function" 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 "block" 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":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 "hard" or rigid with respect to changes or modifications; whereas software is "soft" because it is easy to update or change. Intermediate between software and hardware is "firmware", 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 "hardness" to "softness" 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 "booting" or "booting up". 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":3199,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Nokia_7750_SR-e.jpg","logo":true,"scheme":false,"title":"Nokia 7750 SR-e","vendorVerified":0,"rating":"1.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"nokia-7750-sr-e","companyTitle":"Nokia","companyTypes":["supplier","vendor"],"companyId":5097,"companyAlias":"nokia","description":"<p>The Nokia 7750 SR-e series of IP routers deliver high performance, comprehensive features and resiliency. Designed to stay ahead of evolving service demands driven by the cloud, 5G and the Internet of Things, the 7750 SR product family consists of the 7750 SR-s series, the 7750 SR series, the 7750 SR-a series and the 7750 SR-e series.</p>\r\n<p><span style=\"font-weight: bold;\">Versatile platform</span></p>\r\n<p>For service providers, the Nokia 7750 SR-e enables the delivery of advanced residential, enterprise and mobile services. For webscale companies and enterprises, the 7750 SR-e provides high-performance networking for cloud, data center and wide area networking applications. As an extension to the Nokia 7750 SR product family, the Nokia FP3-based 7750 SR-e scales system capacity from 400 Gb/s half duplex (HD) to 1.2 Tb/s HD. To extend the network edge closer to end users, the 7750 SR-e has the service scale to support multiple applications and functions onto a common platform. The 7750 SR-e’s innovative NEBS-compliant front-to-back thermal design provides the foundation for future growth and delivers investment protection. The 7750 SR-e delivers high-density Gigabit Ethernet (GE) and 10GE density and is ideally suited for GE and 10GE fan-out in subscribed and over-subscribed access and aggregation networks. With high-performance 40GE and 100GE interfaces, the 7750 SR-e can scale access and aggregation networks in step with evolving traffic demands for years to come.</p>\r\n<p><span style=\"font-weight: bold;\">Deterministic performance</span></p>\r\n<p>The Nokia 7750 SR-e leverages the Nokia 400 Gb/s FP3, which combines a multichip architecture and a flexible memory design to provide deterministic packet forwarding performance even when complex processing-intensive operations are required. With the FP3 traffic manager, buffering is always deterministic and does not degrade or cause control plane discards if the buffer rate increases.</p>\r\n<p><span style=\"font-weight: bold;\">Comprehensive features</span></p>\r\n<p>With Nokia’s feature-rich 64-bit Service Router Operating System (SR OS) and extensive QoS, IP/MPLS and segment routing capabilities, the 7750 SR-e has the comprehensive features and tools to define and deliver the most stringent SLAs and end-user quality of experience (QoE) requirements. It supports thousands of IP flows and access control lists with high performance and scales even when multiple advanced features are enabled concurrently. The 7750 SR-e supports a leading number of statistics counts per packet, enabling comprehensive statistics for existing and future applications.</p>\r\n<p><span style=\"font-weight: bold;\">Full array of IP routing functions</span></p>\r\n<p>The 7750 SR-e supports a full array of IP network functions and applications.</p>\r\n<p>Service providers can use the 7750 SR-e in deployments supporting multiple network functions, including Broadband Network Gateway (BNG) for residential subscriber management; provider edge (PE) router for MPLS-enabled enterprise VPN, internet access and cloud services and data center interconnect; mobile applications, including as an aggregation router for 3G, LTE and LTE-A backhaul, a WLAN gateway for Wi-Fi® network aggregation, and a security gateway for securing backhaul networks; and value-added services, including application assurance (AA) and carrier-grade Network Address Translation (NAT).</p>\r\n<p>For webscale companies, the 7750 SR-e delivers leading features for data center aggregation, gateway and interconnect, along with PoP edge and internet peering functions.</p>\r\n<p>For enterprises, the 7750 SR-e provides high-performance IP routing for cloud, data center and wide area networking applications.</p>\r\n<p><span style=\"font-weight: bold;\">High availability</span></p>\r\n<p>For always-on service delivery, the Nokia 7750 SR-e sets the benchmark for high availability. Moving beyond full system redundancy, the robust SR OS supports numerous features to maximize network stability, ensuring IP/MPLS protocols and services run without interruption. These features include innovative nonstop routing, nonstop services, in-service software upgrade (ISSU) and multi-chassis resiliency mechanisms.</p>\r\n<p><span style=\"font-weight: bold;\">Carrier SDN integration</span></p>\r\n<p>Multivendor software-defined networking (SDN) control integration is enabled through OpenFlow, PCEP, BGP-LS and NETCONF/YANG interfaces. In combination with the Nokia Network Services Platform (NSP), the cloud-ready 7750 SR-e can be deployed as part of a Carrier SDN solution, supporting unified service automation and network optimization across IP, MPLS, Ethernet and optical transport layers.</p>\r\n<p><span style=\"font-weight: bold;\">IP/optical integration</span></p>\r\n<p>A standards-based GMPLS user-network interface (UNI) enables the 7750 SR-e to efficiently coordinate IP routing and transport requirements across administrative boundaries and dynamically provision and protect optical segments and end-to-end transport connections.</p>\r\n<p><span style=\"font-weight: bold;\">Network management</span></p>\r\n<p>The 7750 SR-e is fully managed by the Nokia NSP, resulting in integrated network management across the network infrastructure of service providers, webscale companies and enterprises.</p>","shortDescription":"The Nokia 7750 SR-e series of IP routers provides high performance, high availability and fault tolerance.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":3,"sellingCount":9,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Nokia 7750 SR-e","keywords":"","description":"<p>The Nokia 7750 SR-e series of IP routers deliver high performance, comprehensive features and resiliency. Designed to stay ahead of evolving service demands driven by the cloud, 5G and the Internet of Things, the 7750 SR product family consists of the 7750 ","og:title":"Nokia 7750 SR-e","og:description":"<p>The Nokia 7750 SR-e series of IP routers deliver high performance, comprehensive features and resiliency. Designed to stay ahead of evolving service demands driven by the cloud, 5G and the Internet of Things, the 7750 SR product family consists of the 7750 ","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Nokia_7750_SR-e.jpg"},"eventUrl":"","translationId":3200,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3201,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/extreme_networks_CER_2000_Series_Router.png","logo":true,"scheme":false,"title":"Extreme Networks CER 2000 Series Router","vendorVerified":0,"rating":"1.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"extreme-networks-cer-2000-series-router","companyTitle":"Extreme Networks","companyTypes":["vendor"],"companyId":2783,"companyAlias":"extreme-networks","description":"<p>Service providers, more than ever, are looking for ways to reduce network operational costs while increasing new revenue streams through over-the-top services. ExtremeRouting CER 2000 Series Routers are purpose-built to help these providers save on space, power, and cooling while extending wire-speed IP and Multi-Protocol Label Switching (MPLS) services to the network edge without compromising performance.</p>\r\n<p>The CER 2000 is available in 24-port 1 Gigabit Ethernet (GbE) copper and hybrid fiber configurations with four 10 GbE uplink ports. To help ensure high performance, all the ports are capable of forwarding IP and MPLS packets at wire speed without oversubscription.</p>\r\n<p>A broad set of highly scalable IP unicast and multicast routing features, combined with a low total cost of ownership, makes the CER an ideal choice for service providers that want to deliver Layer 2 and Layer 3 business services through a single, easy-to-manage platform.</p>\r\n<p><span style=\"font-weight: bold;\">Highlights:</span></p>\r\n<ul>\r\n<li>Compact 1U, IP/MPLS, NEBS Level 3-certified router, purpose-built for high-performance Ethernet edge routing applications.</li>\r\n<li>Scalable edge router designed to support a full Internet routing table along with MPLS forwarding for advanced business and residential services, service provider data center interconnect, and Internet peering.</li>\r\n<li>Available in 24-port 1 GbE plus 4-port 10 GbE versions for both copper and fiber with non-blocking wire-speed performance and a complete suite of IPv4/IPv6 unicast and multicast routing supporting fast convergence times.</li>\r\n<li>Powered by the field-proven ExtremeRouting Multi-Service IronWare OS that also runs on the ExtremeRouting MLXe Series of high-performance core routers.</li>\r\n<li>Advanced QoS features to enforce strict SLAs at the edge of the network.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Key Applications:</span></p>\r\n<ul>\r\n<li>Edge routing applications in Metro Ethernet networks.</li>\r\n<li>MPLS-based Layer 2 and Layer 3 VPN services.</li>\r\n<li>Provider edge routing for triple-play/ IPTV delivery.</li>\r\n<li>A provider-managed router in end-user customer premises.</li>\r\n<li>Compact BGP route reflector.</li>\r\n<li>Data center or campus border routing.</li>\r\n<li>Virtualized data center or campus applications with multi-VRF.</li>\r\n<li>Data center interconnectivity.</li>\r\n</ul>","shortDescription":"CER 2000 series routers are purpose-built to help these providers save on space, power, and cooling while extending wire-speed IP and Multi-Protocol Label Switching (MPLS) services to the network edge","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":19,"sellingCount":0,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Extreme Networks CER 2000 Series Router","keywords":"","description":"<p>Service providers, more than ever, are looking for ways to reduce network operational costs while increasing new revenue streams through over-the-top services. ExtremeRouting CER 2000 Series Routers are purpose-built to help these providers save on space, p","og:title":"Extreme Networks CER 2000 Series Router","og:description":"<p>Service providers, more than ever, are looking for ways to reduce network operational costs while increasing new revenue streams through over-the-top services. ExtremeRouting CER 2000 Series Routers are purpose-built to help these providers save on space, p","og:image":"https://old.roi4cio.com/fileadmin/user_upload/extreme_networks_CER_2000_Series_Router.png"},"eventUrl":"","translationId":3202,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":230,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Extreme_Networks_BlackDiamond_X8.jpg","logo":true,"scheme":false,"title":"Extreme Networks BlackDiamond X8","vendorVerified":0,"rating":"1.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":0,"alias":"extreme-networks-blackdiamond-x8","companyTitle":"Extreme Networks","companyTypes":["vendor"],"companyId":2783,"companyAlias":"extreme-networks","description":"Cloud-Scale Data Center Switch\r\nMeets HPC, IXP, and data center demands\r\nHigh-density wire-speed 10GbE, 40GbE, and 100GbE connectivity\r\nUnmatched performance with 20.48Tbs capacity\r\n\r\n \r\nMeets HPC, IXP, and data center demands\r\nHigh-density wire-speed 10GbE, 40GbE, and 100GbE connectivity\r\nUnmatched performance with 20.48Tbs capacity\r\nClick to talk to a network expert\r\n\r\nData centers today demand highly virtualized, converged, and scalable infrastructure. Multi-tenancy and cloud computing are driving the need for simplicity and cost efficiency from the network fabric, along with a need for expandability, high performance, and service up-time. The ExtremeSwitching X8 platform provides seamless any-to-any connectivity through a simple, scalable, and centrally orchestrated network.\r\n\r\nDesigned for cloud-scale requirements of data centers, high-performance computing (HPC), and Internet exchange points (IXP), the ExtremeSwitching X8 provides a low-latency, high-performance switch fabric with high-density wire-speed 10GbE, 40GbE, and 100GbE connectivity for edge-to-core applications, all in a compact footprint using only one-third of a standard rack. The ExtremeSwitching X8 eliminates expensive multi-tier architectures and the challenges of inter-device connectivity, uplink bandwidth, and latency. The ExtremeSwitching X8 also leverages a low-power design ideal for green operations and high degrees of energy efficiency, resulting in lower total cost of ownership (TCO).\r\n\r\n\r\nHigh-density 1/10GbE, 40GbE, and 100GbE switch for data center consolidation\r\n768 ports of 10GbE SFP+ per switch, 2,304 ports per rack\r\n384 ports of 100/1000/10000MbE RJ45 per switch, 1,152 ports per rack\r\n384 ports of 1GbE SFP per switch, 1,152 ports per rack (using 10GbE)\r\n192 ports of 40GbE QSFP+ per switch, 576 ports per rack\r\n32 ports of 100GbE CFP2 per switch, 96 ports per rack\r\nOrthogonal architecture with 20.48Tbps switching capacity\r\n2.3 μSec port-to-port latency\r\nHigh-scale routing with 1 million forwarding entries\r\nPowered by time-tested, modular ExtremeXOS® operating system with resilient and intelligent virtualization features and hardware switching of up to 1 million virtual machines\r\nConverged open fabric for reliable IP-based storage services and transit for FCoE traffic\r\nLow power consumption of 5.6 watts per 10GbE or 22.5 watts per 40GbE port for low total cost of ownership\r\nExtreme Networks How-To Videos\r\n\r\n20+Tbps switching capacity\r\n2.56Tbps bandwidth per slot\r\n192 x 40GbE or 768 x 10GbE or 32 x 100GbE\r\nHigh-availability design\r\n\r\nN+1 switching, power, and fan redundancy\r\nN+N Power GRID redundancy\r\nLow latency\r\n\r\n2.3 µsec\r\nHigh-density design\r\n\r\n14.5 RU (1/3 rack )\r\nVirtualization support\r\n\r\n128K virtual machines\r\nVirtual port profile (VPP) support\r\nVirtual machine lifecycle management with XNV\r\nStorage convergence\r\n\r\nNFS, CIFS, iSCSI, FCoE\r\nLower TCO\r\n\r\nHigh-efficiency 100GbE CFP2 optics\r\n5.6W per 10GbE port\r\nPure front-to-back cooling\r\nIntelligent power management\r\nVariable-speed fans","shortDescription":"Extreme Networks BlackDiamond X8 - Cloud-Scale Data Center Switch\r\nMeets HPC, IXP, and data center demands\r\nHigh-density wire-speed 10GbE, 40GbE, and 100GbE connectivity\r\nUnmatched performance with 20.48Tbs capacity","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":17,"sellingCount":13,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Extreme Networks BlackDiamond X8","keywords":"ports, 10GbE, with, 100GbE, 40GbE, rack, switch, connectivity","description":"Cloud-Scale Data Center Switch\r\nMeets HPC, IXP, and data center demands\r\nHigh-density wire-speed 10GbE, 40GbE, and 100GbE connectivity\r\nUnmatched performance with 20.48Tbs capacity\r\n\r\n \r\nMeets HPC, IXP, and data center demands\r\nHigh-density w","og:title":"Extreme Networks BlackDiamond X8","og:description":"Cloud-Scale Data Center Switch\r\nMeets HPC, IXP, and data center demands\r\nHigh-density wire-speed 10GbE, 40GbE, and 100GbE connectivity\r\nUnmatched performance with 20.48Tbs capacity\r\n\r\n \r\nMeets HPC, IXP, and data center demands\r\nHigh-density w","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Extreme_Networks_BlackDiamond_X8.jpg"},"eventUrl":"","translationId":231,"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3191,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/MX_Series_5G_Universal_Routing_Platform.png","logo":true,"scheme":false,"title":"Juniper MX Series 5G Universal Routing Platform","vendorVerified":0,"rating":"1.40","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":2,"alias":"juniper-mx-series-5g-universal-routing-platform","companyTitle":"Juniper Networks","companyTypes":["supplier","vendor"],"companyId":2784,"companyAlias":"juniper-networks","description":"<p>Virtualized, full-featured, carrier-grade router is ideal for NFV environments, rapid service introduction, and cost-effective service scale-out.</p>\r\n<p><span style=\"font-weight: bold;\">virtual MX (vMX)</span></p>\r\n<p>Виртуализированный полнофункциональный маршрутизатор операторского уровня идеально подходит для сред NFV, быстрого внедрения услуг и экономически эффективного масштабирования услуг.</p>\r\n<p><span style=\"font-weight: bold;\">MX5</span></p>\r\n<p>Compact 40 Gbps router is software-upgradable through 160 Gbps of system capacity; ideal for enterprise applications as well as space- and power-constrained service provider facilities.</p>\r\n<p><span style=\"font-weight: bold;\">MX10</span></p>\r\n<p>Compact 80 Gbps router is software-upgradable through 160 Gbps of system capacity; ideal for enterprise applications as well as space- and power-constrained service provider facilities.</p>\r\n<p><span style=\"font-weight: bold;\">MX40</span></p>\r\n<p>Compact 120 Gbps router is software-upgradable through 160 Gbps of system capacity; ideal for enterprise applications as well as space- and power-constrained service provider facilities.</p>\r\n<p><span style=\"font-weight: bold;\">MX80</span></p>\r\n<p>Compact 160 Gbps router is ideal for enterprise applications as well as space- and power-constrained service provider facilities.</p>\r\n<p><span style=\"font-weight: bold;\">MX104</span></p>\r\n<p>Versatile 160 Gbps router offers a high level of redundancy; optimized for mobile backhaul, metro Ethernet, aggregation, and enterprise WAN applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX150</span></p>\r\n<p>The compact MX150 is a high-performance, feature-rich edge router that is ideally suited for lower bandwidth service provider and enterprise applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX204</span></p>\r\n<p>A compact multiservices router, the MX204 delivers ultra-high density in a 1 U power-efficient form factor to address the widest variety of service provider, mobile, data center, and cloud applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX240</span></p>\r\n<p>Modular router offers up to 3 Tbps of system capacity and embedded MACsec and IPsec encryption in a compact form factor; optimized for cloud, campus, enterprise, data center, service provider edge, cable, and mobile service core deployments.</p>\r\n<p><span style=\"font-weight: bold;\">MX480</span></p>\r\n<p>Modular router delivers up to 9 Tbps of system capacity and embedded MACsec and IPsec encryption for cloud, campus, enterprise, data center, service provider edge, cable, and mobile service core deployments.</p>\r\n<p><span style=\"font-weight: bold;\">MX960</span></p>\r\n<p>Modular router delivers up to 12 Tbps of system capacity and embedded MACsec and IPsec encryption for large cloud, data center, service provider, cable, and mobile service core deployments.</p>\r\n<p><span style=\"font-weight: bold;\">MX2008</span></p>\r\n<p>40-Tbps modular, space-optimized carrier-grade router that provides ultra-high-density 10GbE, 40GbE, and 100GbE interfaces to help network operators efficiently address edge and core applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX2010</span></p>\r\n<p>40-Tbps modular carrier-grade router that provides ultra-high-density 10GbE, 40GbE, and 100GbE interfaces to help network operators efficiently address edge and core applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX2020</span></p>\r\n<p>80-Tbps carrier-grade router that provides ultra-high-density 10GbE, 40GbE, and 100GbE interfaces to help network operators efficiently address edge and core applications.</p>\r\n<p><span style=\"font-weight: bold;\">MX10003</span></p>\r\n<p>Compact universal routing platform with ultra-high system capacity and interface density for long-term investment protection.</p>\r\n<p><span style=\"font-weight: bold;\">MX10008 и MX10016</span></p>\r\n<p>Space- and power-optimized routing platforms with innovative universal chassis design deliver superior performance, versatility, and capacity.</p>\r\n<p> </p>\r\n<p><span style=\"text-decoration: underline;\"><span style=\"font-weight: bold;\">Features:</span></span></p>\r\n<p><span style=\"font-weight: bold;\">Service Agility</span></p>\r\n<p>Supports broadest range of business, residential, infrastructure, and enterprise applications and services.</p>\r\n<p><span style=\"font-weight: bold;\">Best-in-Class Architecture</span></p>\r\n<p>A highly redundant platform powered by Junos OS, the MX Series offers always-on reliability and high performance at massive scale.</p>\r\n<p><span style=\"font-weight: bold;\">SDN Enabled</span></p>\r\n<p>Seamless integration with standard-based SDN controllers such as the Contrail Cloud Platform makes the MX Series platform an SDN gateway between physical and virtual network elements.</p>\r\n<p><span style=\"font-weight: bold;\">Service Integration</span></p>\r\n<p>Integrates a wide set of services—including carrier-grade NAT (CGNAT), stateful firewall, and deep packet inspection (DPI)—to address the widest range of applications and support network and service consolidation.</p>\r\n<p><span style=\"font-weight: bold;\">Physical and Virtual, with No Compromise</span></p>\r\n<p>Consistent feature set across physical and virtual MX Series platforms ensures operational and service consistency.</p>\r\n<p><span style=\"font-weight: bold;\">Long-Term Investment Protection</span></p>\r\n<p>Offers future-proof scale for long-term growth as well as investment protecting upgrade paths for existing MX Series customers.</p>","shortDescription":"The MX Series 5G platform is the networking platform to support a standards-based 5G user plane that can be applied to both existing and future MX routers to converge wired and wireless networking.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":20,"sellingCount":1,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Juniper MX Series 5G Universal Routing Platform","keywords":"","description":"<p>Virtualized, full-featured, carrier-grade router is ideal for NFV environments, rapid service introduction, and cost-effective service scale-out.</p>\r\n<p><span style=\"font-weight: bold;\">virtual MX (vMX)</span></p>\r\n<p>Виртуализированный полнофункциональный","og:title":"Juniper MX Series 5G Universal Routing Platform","og:description":"<p>Virtualized, full-featured, carrier-grade router is ideal for NFV environments, rapid service introduction, and cost-effective service scale-out.</p>\r\n<p><span style=\"font-weight: bold;\">virtual MX (vMX)</span></p>\r\n<p>Виртуализированный полнофункциональный","og:image":"https://old.roi4cio.com/fileadmin/user_upload/MX_Series_5G_Universal_Routing_Platform.png"},"eventUrl":"","translationId":3192,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":232,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/QFabric_System.jpg","logo":true,"scheme":false,"title":"QFabric System","vendorVerified":0,"rating":"1.40","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":2,"alias":"qfabric-system","companyTitle":"Juniper Networks","companyTypes":["supplier","vendor"],"companyId":2784,"companyAlias":"juniper-networks","description":"The QFabric® System is composed of multiple components working together as a single switch. It flattens the network to a single tier to provide high-performance, any-to-any connectivity and management simplicity, making it the ideal network foundation for cloud-ready, virtualized data centers.\r\nThe QFabric System is composed of multiple components working together as a single switch to provide high-performance, any-to-any connectivity and management simplicity in the data center. The QFabric System flattens the entire data center network to a single tier where all access points are equal, eliminating the effects of network locality and making it the ideal network foundation for cloud-ready, virtualized data centers.\r\nQFabric is a highly scalable system that improves application performance with low latency and converged services in a non-blocking, lossless architecture that supports Layer 2, Layer 3, and Fibre Channel over Ethernet capabilities.\r\n<span style=\"font-weight: bold;\">Distributed switch composed of three components:</span>\r\nQFX3500/QFX3600/QFX5100 QFabric Node\r\nQFX3600-I/QFX3008-I QFabric Interconnect\r\nQFX3100 QFabric Director\r\n\r\n<span style=\"font-weight: bold;\">Features</span>\r\n\r\nScales to 40 Tbps to deliver unprecedented capacity beyond 10GbE at the access layer.\r\nUltra-low Deterministic Latency is ideal for supporting latency-sensitive applications, east-west traffic flows, virtualization, cloud, and other high-performance data center initiatives.\r\nSingle-Switch Management greatly simplifies data center operations with less complexity and lower power, space, cooling, and operational costs.\r\nCarrier-Class Solution requires no downtime for reconfiguration or maintenance.\r\nScales to Thousands of Ports within a single-tier network in a "pay-as-you-grow" model.\r\nIncremental Design allows conversion of QFX Series switches from top-of-rack to QFabric devices.\r\n\r\n<span style=\"font-weight: bold; \">QFabric System Models</span>\r\nQFX3000-M \r\nQFX3000-G ","shortDescription":"The QFabric® System is composed of multiple components working together as a single switch.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":15,"sellingCount":6,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"QFabric System","keywords":"QFabric, data, network, System, single, center, composed, ideal","description":"The QFabric® System is composed of multiple components working together as a single switch. 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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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":94,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Cisco_4000_Series_Integrated_Services_Routers.jpg","logo":true,"scheme":false,"title":"Cisco 4000 Series Integrated Services Routers","vendorVerified":0,"rating":"2.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":125,"alias":"cisco-4000-series-integrated-services-routers","companyTitle":"Cisco","companyTypes":["supplier","vendor"],"companyId":170,"companyAlias":"cisco","description":"<p>The Cisco 4000 Family Integrated Services Router (ISR) revolutionizes WAN communications in the enterprise branch. With new levels of built-in intelligent network capabilities and convergence, it specifically addresses the growing need for application-aware networking in distributed enterprise sites. These locations tend to have lean IT resources. But they often also have a growing need for direct communication with both private data centers and public clouds across diverse links, including Multiprotocol Label Switching (MPLS) VPNs and the Internet.</p>\r\n<p>The Cisco 4000 Family contains the following platforms: the 4461, 4451, 4431, 4351, 4331, 4321 and 4221 ISRs.</p>\r\n<p><span style=\"font-weight: bold;\">Features and Benefits</span></p>\r\n<p>Cisco 4000 Family ISRs provide you with Cisco® Software Defined WAN (SDWAN) software features and a converged branch infrastructure. Along with superior throughput, these capabilities form the building blocks of next-generation branch-office WAN solutions.</p>\r\n<p><span style=\"font-weight: bold;\">Cisco Software Defined WAN</span></p>\r\n<p>Cisco SDWAN is a set of intelligent software services that allow you to reliably and securely connect users, devices, and branch office locations across a diverse set of WAN transport links. SDWAN-enabled routers like the ISR 4000 dynamically route traffic across the “best” link based on up-to-the-minute application and network conditions for great application experiences. You get tight control over application performance, bandwidth usage, data privacy, and availability of your WAN links - control that you need as your branches conduct greater volumes of mission-critical business.</p>\r\n<p><span style=\"font-weight: bold;\">Cisco Converged Branch Infrastructure</span></p>\r\n<p>The Cisco 4000 Series ISRs consolidate many must-have IT functions, including network, compute, and storage resources. The high-performance, integrated routers run multiple concurrent services, including encryption, traffic management, and WAN optimization, without slowing your data throughput. And you can activate new services on demand through a simple licensing change.</p>\r\n<p><span style=\"font-weight: bold;\">Cisco Intent Based Networking and Digital Network Architecture (Cisco DNA)</span></p>\r\n<p>The last few years has seen a rapid transformation and adoption of digital technologies. This puts pressure on the on the Network teams supporting this changing infrastructure - especially when provisioning, managing, monitoring and troubleshooting these diverse devices. Additionally innovations such as Software Defined WAN (SDWAN), Network Function Virtualization (NFV), Open APIs and Cloud Management show great promise in transforming Organizations IT networks. This transformation raises further questions and challenges for the IT teams.</p>\r\n<p>The Cisco Digital Network Architecture (Cisco DNA) is an open, extensible, software-driven architecture that provides for faster innovation, helping to generate deeper insights, and deliver exceptional experiences across many different applications. Cisco DNA relies on intent-based networking, a revolutionary approach in networking that helps organizations automate, simplify, and secure the network.</p>\r\n<p><span style=\"font-weight: bold;\">The intent-based Cisco DNA network is:</span></p>\r\n<ul>\r\n<li>Informed by Context: Interprets every byte of data that flows across it, resulting in better security, more customized experiences, and faster operations.</li>\r\n<li>Powered by Intent: Translates your intent into the right network configuration, making it possible to manage and provision multiple devices and things in minutes.</li>\r\n<li>Driven by Intuition: Continually learns from the massive amounts of data flowing through it and turns that data into actionable insight. Helps you solve issues before they become problems and learn from every incident.</li>\r\n</ul>\r\n<p>Cisco DNA Center provides a centralized management dashboard across your entire network — the branch, campus, data center, and cloud. Rather than relying on box-by-box management, you can design, provision, and set policy end-to-end from the single Cisco DNA Center interface. This allows you to respond to organizational needs faster and to simplify day-to-day operations. Cisco DNA Analytics and Assurance and Cisco Network Data Platform (NDP) help you get the most from your network by continuously collecting and putting insights into action. Cisco DNA is open, extensible, and programmable at every layer. It integrates Cisco and third-party technology, open APIs, and a developer platform, to support a rich ecosystem of network-enabled applications.</p>","shortDescription":"The 4000 Series represents a new, multi-service, branch platform architecture. It helps you connect any user over any connection, and offer a superior user experience.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":0,"sellingCount":0,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Cisco 4000 Series Integrated Services Routers","keywords":"Cisco, network, include, Intelligent, with, integrated, Ethernet, capabilities","description":"<p>The Cisco 4000 Family Integrated Services Router (ISR) revolutionizes WAN communications in the enterprise branch. With new levels of built-in intelligent network capabilities and convergence, it specifically addresses the growing need for application-aware","og:title":"Cisco 4000 Series Integrated Services Routers","og:description":"<p>The Cisco 4000 Family Integrated Services Router (ISR) revolutionizes WAN communications in the enterprise branch. With new levels of built-in intelligent network capabilities and convergence, it specifically addresses the growing need for application-aware","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Cisco_4000_Series_Integrated_Services_Routers.jpg"},"eventUrl":"","translationId":94,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":1394,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Cisco_Small_Business_kommutatory.jpg","logo":true,"scheme":false,"title":"Cisco Small Business коммутаторы","vendorVerified":0,"rating":"2.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":125,"alias":"cisco-small-business-kommutatory","companyTitle":"Cisco","companyTypes":["supplier","vendor"],"companyId":170,"companyAlias":"cisco","description":null,"shortDescription":null,"type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":1,"sellingCount":6,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Cisco Small Business коммутаторы","keywords":"Cisco, Small, Business, коммутаторы","description":"","og:title":"Cisco Small Business коммутаторы","og:description":"","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Cisco_Small_Business_kommutatory.jpg"},"eventUrl":"","translationId":7086,"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3193,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Huawei_AR2200_Series_Enterprise_Routers.jpg","logo":true,"scheme":false,"title":"Huawei AR2200 Series Enterprise Routers","vendorVerified":0,"rating":"2.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":4,"alias":"huawei-ar2200-series-enterprise-routers","companyTitle":"Huawei","companyTypes":["vendor"],"companyId":2743,"companyAlias":"huawei","description":"<p><span style=\"text-decoration: underline;\"><span style=\"font-weight: bold;\">Features and benefits</span></span></p>\r\n<p><span style=\"font-weight: bold;\">Applications in one box, Reduce TCO</span></p>\r\n<p>The AR2200 routers reduce equipment and deployment costs due to the integrated routing, switching, 3G, voice, and security functions into a single device. At the same time, The AR2200 realizes enterprises flexible access with rich interfaces adapting to a variety of terminals.</p>\r\n<p><span style=\"font-weight: bold;\">Industry-Leading Voice Quality and User Experience</span></p>\r\n<p>Enterprise-class voice communication is flexible and efficient, as the AR2200 voice features integrate with data networks.</p>\r\n<ul>\r\n<li>Basic voice functions are provided by the built-in PBX, SIP server, and SIP access gateway</li>\r\n<li>Value-added voice services include multi-party communication, IVR automatic connection, ring-back-tone, parallel ringing, sequential ringing, one number link you (ONLY), bill management, and subscriber management.</li>\r\n<li>Intelligent call routing enables exceptional voice service reliability.</li>\r\n<li>The AR2200 routers can be connected with the NGN/IMS/PBX/terminal of major vendors.</li>\r\n<li>The Quality of Experience (QoE) feature monitors voice service quality in real time.</li>\r\n<li>Jitter buffer, echo cancellation, and packet loss compensation combine to deliver a superior user experience.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Secure Service Access Protects Networks and Users</span></p>\r\n<p>While delivering enterprise-class network services, the AR3260 router provides robust network security. Comprehensive security solutions include user access control, packet detection, and active attack defense.</p>\r\n<ul>\r\n<li>Features a built-in firewall and IPS, which acts as the first line of defense.</li>\r\n<li>Port authentication technologies include 802.1x authentication, MAC address authentication, and portal authentication.</li>\r\n<li>User and device authentication methods include RADIUS and HWTACACS.</li>\r\n<li>VPN technologies include IPSec VPN, GRE VPN, DSVPN, L2TP VPN.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Better Experience, Business Continuity</span></p>\r\n<p><span style=\"font-weight: bold;\">Multi-cores architecture, Industry-Leading performance</span></p>\r\n<p>The AR2200 routers use a multi-core CPU and non-blocking switching structure to provide industry-leading system performance.</p>\r\n<ul>\r\n<li>The multi-core CPU speeds up concurrent data and voice service processing, supporting a large number of services.</li>\r\n<li>Achieves maximum traffic throughput with non-blocking switching.• The bus channel bandwidth of a single slot is up to 10 Gbps.</li>\r\n<li>Delivers high performance and service reliability through independent protocol management, service processing, and data switching.</li>\r\n</ul>\r\n<p>To meet enterprise requirements for network expansion and rapid service deployment, the AR2200 routers:</p>\r\n<ul>\r\n<li>Integrates routing and switching functions to simplify device configuration and maintenance by improving data switching efficiency between interface cards.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Low cost, High reliability</span></p>\r\n<p>To guarantee the reliability of the equipment layer and network layer, the AR2200 series support hot-swaps technology and redundant components design, a series of fault detection and judgment mechanisms, which can shorten the service interruption time.</p>\r\n<ul>\r\n<li>Assures service reliability and network stability with hot-swappable interface cards and redundant components, including fan modules.</li>\r\n<li>Link backup for enterprise services improves reliability.</li>\r\n<li>MS level Fault detection mechanisms, shorten the service interruption time.</li>\r\n<li>Local survival, improve the voice reliability of branch network.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Intelligent Service Deployment</span></p>\r\n<p>As the enterprise grows, requirements for service deployment increase. To meet these growing demands, the AR2200 routers provide convenient configuration options:</p>\r\n<ul>\r\n<li>Mini-USB port to configure the devices using a GUI.</li>\r\n<li>USB drive to configure devices for plug-and-play.</li>\r\n<li>Auto-config feature to automatically distribute configurations to devices.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Cooperation platform, On Demand applications</span></p>\r\n<p><span style=\"font-weight: bold;\">Open Service Platform, Enterprise-level APP</span></p>\r\n<p>The AR2200 routers provide a unified communication solution for enterprise customers. It uses the Open Service Platform (OSP) to interconnect with third-party IT systems. Customers, agents, third-party vendors, and manufacturers can develop unified communication systems by using the AR2200 routers.</p>\r\n<ul>\r\n<li>Integrate and customize services quickly.</li>\r\n<li>Save money and simplify management, as service integration does not require dedicated servers.</li>\r\n<li>Services synchronized with cloud-side services and local services are processed locally, which improves service quality and efficiency.</li>\r\n</ul>\r\n<p><span style=\"font-weight: bold;\">Standard MIB provided by VRP, Simplified Network and Device Management</span></p>\r\n<p>The AR2200 routers make network and device management simple:</p>\r\n<ul>\r\n<li>Manage devices easily with the eSight network management system.</li>\r\n<li>Monitor links in real time using the NQA feature.</li>\r\n<li>Maintain peak network performance by using the NetStream feature to view traffic characteristics and statistics, as well as optimization according to usage.</li>\r\n</ul>","shortDescription":"The AR2200 routers are next-generation enterprise-class routers based on the Huawei proprietary Versatile Routing Platform (VRP).","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":6,"sellingCount":8,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Huawei AR2200 Series Enterprise Routers","keywords":"","description":"<p><span style=\"text-decoration: underline;\"><span style=\"font-weight: bold;\">Features and benefits</span></span></p>\r\n<p><span style=\"font-weight: bold;\">Applications in one box, Reduce TCO</span></p>\r\n<p>The AR2200 routers reduce equipment and deployment cos","og:title":"Huawei AR2200 Series Enterprise Routers","og:description":"<p><span style=\"text-decoration: underline;\"><span style=\"font-weight: bold;\">Features and benefits</span></span></p>\r\n<p><span style=\"font-weight: bold;\">Applications in one box, Reduce TCO</span></p>\r\n<p>The AR2200 routers reduce equipment and deployment cos","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Huawei_AR2200_Series_Enterprise_Routers.jpg"},"eventUrl":"","translationId":3194,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":3196,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/FlexNetwork_MSR3000_Router_Series.png","logo":true,"scheme":false,"title":"HPE FlexNetwork MSR3000 Router Series","vendorVerified":0,"rating":"2.00","implementationsCount":0,"suppliersCount":0,"supplierPartnersCount":452,"alias":"hpe-marshrutizatory-serii-hpe-flexnetwork-msr3000","companyTitle":"Hewlett Packard Enterprise","companyTypes":["supplier","vendor"],"companyId":172,"companyAlias":"hewlett-packard-enterprise","description":"<p>The HPE MSR3000 Router Series delivers high-performance medium to large branch routing up to 5 Mpps in a cost-optimized form factor. Featuring integrated routing, switching, security, and SIP with no additional licensing, you can boost your service delivery while simplifying management of your corporate WAN.</p>\r\n<p>With the Open Application Platform module, the MSR3000 Router Series offers a wide range of virtualized applications. Its distributed architecture and high reliability also strengthen the resiliency of medium to large branches.</p>\r\n<p><span style=\"font-weight: bold;\">What's new:</span></p>\r\n<ul>\r\n<li>Enhances security with built-in IPS and stateful firewall, with optional HPE IPS filter subscription.</li>\r\n<li>WAN survivability with 4G LTE SIC modules, and flexible power options.</li>\r\n<li>New Serial, GbE and Gig-T SIC modules increase configuration flexibility.</li>\r\n<li>High-density voice modules and channelized POS access to cover.</li>\r\n<li>Additional features such as ADVPN and hierarchical QoS.</li>\r\n</ul>\r\n<p> </p>\r\n<p><span style=\"font-weight: bold;\">Features:</span></p>\r\n<p><span style=\"font-weight: bold;\">Reduces Complexity and Simplifies Your Network</span></p>\r\n<p>The HPE MSR3000 Router Series simplifies your network through integrated routing, switching, security, and voice, and combines the flexibility of modular upgrades to deliver high-performance medium-to-large branch routing.</p>\r\n<p>Makes administration easier with HPE Intelligent Management Center (IMC) Software.</p>\r\n<p>Reduces management complexity with zero-touch deployment (ZTP) and Dynamic VPN.</p>\r\n<p><span style=\"font-weight: bold;\">Enhances Time to Service and Branch Performance</span></p>\r\n<p>The HPE MSR3000 Router Series offers high performance routing with up to 5 Mpps forwarding and 3.3 Gbps of IPSec encryption throughput to meet bandwidth requirements of branch traffic.</p>\r\n<p>Supports branch services with a comprehensive feature set and eases the cloud transition with integrated security.</p>\r\n<p>Satisfies medium to large branches with advanced hardware architecture and high port density.</p>\r\n<p><span style=\"font-weight: bold;\">Increase Your Return on Investment</span></p>\r\n<p>The HPE MSR3000 Router Series is a modular platform with a wide range of connectivity options that enables the right design for your needs.</p>\r\n<p>Reduces your TCO through open standards, power and space savings, and energy-efficient hardware.</p>\r\n<p>Deploy advanced features with no additional licensing.</p>\r\n<p><span style=\"font-weight: bold;\">Boosts Agility and Resiliency</span></p>\r\n<p>The HPE MSR3000 Router Series provides branch service and business continuity with 4G/LTE and 3G WAN.</p>\r\n<p>With the Open Application Platform module, support HPE AllianceOne applications such as WAN acceleration and Microsoft Skype for Business (Lync).</p>\r\n<p>Delivers an open standards approach to your network infrastructure.</p>\r\n<p>With advanced hardware architecture and FPBA modules, you get reliable, high-performance functionality with multi-core processors.</p>","shortDescription":"The HPE MSR3000 Router Series delivers high-performance medium to large branch routing up to 5 Mpps in a cost-optimized form factor.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":9,"sellingCount":18,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"HPE FlexNetwork MSR3000 Router Series","keywords":"","description":"<p>The HPE MSR3000 Router Series delivers high-performance medium to large branch routing up to 5 Mpps in a cost-optimized form factor. Featuring integrated routing, switching, security, and SIP with no additional licensing, you can boost your service delivery","og:title":"HPE FlexNetwork MSR3000 Router Series","og:description":"<p>The HPE MSR3000 Router Series delivers high-performance medium to large branch routing up to 5 Mpps in a cost-optimized form factor. Featuring integrated routing, switching, security, and SIP with no additional licensing, you can boost your service delivery","og:image":"https://old.roi4cio.com/fileadmin/user_upload/FlexNetwork_MSR3000_Router_Series.png"},"eventUrl":"","translationId":3197,"dealDetails":null,"roi":null,"price":null,"bonusForReference":null,"templateData":[{"id":87,"title":"Enterprise routers"}],"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":716,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Kommutatory_Cisco_Nexus_serii_9000.jpg","logo":true,"scheme":false,"title":"Cisco Nexus 9000 Series Switches","vendorVerified":0,"rating":"2.00","implementationsCount":2,"suppliersCount":0,"supplierPartnersCount":125,"alias":"cisco-nexus-9000-series-switches","companyTitle":"Cisco","companyTypes":["supplier","vendor"],"companyId":170,"companyAlias":"cisco","description":"Cloud Scale ASIC technology\r\nInvestment protection with multi-speed ports 10/25/50/100G and line rate encryption, so you can scale as needed. Integrated and streaming analytics brings advance security. Unified ports supporting 10/25GbE and 8/16/32G fiber channel provides convergence.\r\nProgrammability for DevOps\r\nThe industry’s highly programmable switch with open APIs is ideal for DevOps environments. Nexus 9000 open programmability supports built-in DevOps automation tools such as Puppet, Chef, and Ansible.\r\nAutomation\r\nCisco ACI makes the application the focal point of infrastructure. It enables an agile, open, and secure architecture. You can reduce TCO, automate IT tasks, and accelerate data center application deployments.\r\nArchitectural flexibility\r\nGet energy-efficient deployment of 3-tier or leaf-spine architecture. Get flexible port configuration of 1/10/25/40/50/100 GE with storage networking support. This provides a foundation for ACI, our industry-leading automation solution.\r\nScalability\r\nGain up to 172.8 Tbps of nonblocking performance with less than 5-microsecond latency. The switches offer wire-speed gateway, bridging, routing, and our Border Gateway Protocol control plane for VXLAN. Segment routing eases virtualization.\r\nReal-time visibility and telemetry\r\nBuilt-in sensors support Cisco Tetration Analytics for rich traffic flow telemetry and line-rate data collection. Real-time buffer use per port and per queue helps keep track of application traffic patterns.\r\n","shortDescription":"Build a next-generation automated data center. Our Nexus 9000 Series delivers proven high performance and density, low latency, and exceptional power efficiency in a range of form factors. The switches operate in Cisco NX-OS Software or Application Centric Infrastructure (ACI) modes with ground-breaking Cloud Scale ASIC technology. They are ideal for traditional or fully automated data center deployments.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":11,"sellingCount":11,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Cisco Nexus 9000 Series Switches","keywords":"with, application, open, DevOps, Cisco, telemetry, automation, traffic","description":"Cloud Scale ASIC technology\r\nInvestment protection with multi-speed ports 10/25/50/100G and line rate encryption, so you can scale as needed. Integrated and streaming analytics brings advance security. Unified ports supporting 10/25GbE and 8/16/32G fiber chann","og:title":"Cisco Nexus 9000 Series Switches","og:description":"Cloud Scale ASIC technology\r\nInvestment protection with multi-speed ports 10/25/50/100G and line rate encryption, so you can scale as needed. Integrated and streaming analytics brings advance security. Unified ports supporting 10/25GbE and 8/16/32G fiber chann","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Kommutatory_Cisco_Nexus_serii_9000.jpg"},"eventUrl":"","translationId":717,"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":488,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Juniper_QFX_kommutatory.png","logo":true,"scheme":false,"title":"Juniper QFX Series switches","vendorVerified":0,"rating":"2.10","implementationsCount":2,"suppliersCount":0,"supplierPartnersCount":2,"alias":"juniper-qfx-series-switches","companyTitle":"Juniper Networks","companyTypes":["supplier","vendor"],"companyId":2784,"companyAlias":"juniper-networks","description":"QFX5100\r\nThe QFX5100 Switches are low-latency, high-performance 10GbE/40GbE switches that act as a flexible building block for multiple data center fabric architectures.\r\nQFX5200\r\nQFX5200 fixed-configuration switches offer flexible connectivity options, from 10GbE to 100GbE, making them ideally suited for leaf deployments in next-generation IP data center fabrics.\r\nQFX10000\r\nThe QFX10000 Switches are highly scalable, high-density platforms that support a variety of 10GbE/40GbE/100GbE deployments, providing a robust foundation for the most demanding data centers.\r\nHigh performance, low latency\r\nWith throughput of up to 6 Tbps per slot, QFX Series switches deliver sustained wire-speed switching with low latency and jitter for virtualized data center environments.\r\nHighly available\r\nRedundant fabrics, power and cooling, combined with separate control and data planes, ensure maximum system availability.\r\nData center fabric building blocks\r\nQFX Series switches provide the universal building blocks for multiple data center fabric architectures, including Junos Fusion, QFabric System, Virtual Chassis and Virtual Chassis Fabric.\r\nStandards-based\r\nStandards-based bridging, routing, VMware NSX Layer 2 gateway, and Fibre Channel technology enable interoperability and easy integration.","shortDescription":"QFX Series switches are high-performance, high-density platforms that satisfy the needs of today’s most demanding enterprise and service provider environments. Designed for top-of-rack, end-of-row, and spine-and-core aggregation deployments in modern data centers, QFX Series switches can be deployed as 10GbE, 40GbE or 100GbE access, spine, core or aggregation devices in Virtual Chassis, Virtual Chassis Fabric, Multi-Chassis LAG and Junos Fusion architectures.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":8,"sellingCount":10,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Juniper QFX Series switches","keywords":"data, center, switches, 10GbE, building, fabric, Series, latency","description":"QFX5100\r\nThe QFX5100 Switches are low-latency, high-performance 10GbE/40GbE switches that act as a flexible building block for multiple data center fabric architectures.\r\nQFX5200\r\nQFX5200 fixed-configuration switches offer flexible connectivity options, from 1","og:title":"Juniper QFX Series switches","og:description":"QFX5100\r\nThe QFX5100 Switches are low-latency, high-performance 10GbE/40GbE switches that act as a flexible building block for multiple data center fabric architectures.\r\nQFX5200\r\nQFX5200 fixed-configuration switches offer flexible connectivity options, from 1","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Juniper_QFX_kommutatory.png"},"eventUrl":"","translationId":489,"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]},{"id":411,"logoURL":"https://old.roi4cio.com/fileadmin/user_upload/Kommutatory_Cisco_Nexus_serii_7000.jpg","logo":true,"scheme":false,"title":"Cisco Nexus 7000 Series Switches","vendorVerified":0,"rating":"2.40","implementationsCount":2,"suppliersCount":0,"supplierPartnersCount":125,"alias":"cisco-nexus-7000-series-switches","companyTitle":"Cisco","companyTypes":["supplier","vendor"],"companyId":170,"companyAlias":"cisco","description":"Build a Next-Generation Network\r\n\r\nCisco Nexus 7000 Series Switches create the network foundation for your next-generation Unified Fabric data center. Modular switches, including the Cisco Nexus 7000 and 7700 Series, deliver a comprehensive Cisco NX-OS feature set and open source programmable tools for software-defined network (SDN) deployments. They offer high-density 10, 40, and 100 Gigabit Ethernet with application awareness and performance analytics\r\n\r\nFeatures and Capabilities\r\n\r\nHigh Performance with Comprehensive Feature Set\r\nCisco Nexus 7000 Series Switches offer one of the most comprehensive data center network feature sets in a single platform. They offer high performance, high port density, and a full feature set for data center aggregation, end-of-row, and data center interconnect (DCI) deployments in a highly resilient modular platform.\r\n\r\nThe Cisco Nexus 7000 Series runs on Cisco NX-OS Software. It was specifically developed for the most mission-critical enterprise and service provider deployments.\r\n\r\nThe Cisco Nexus 7000 Series was designed around three principles:\r\n\r\nInfrastructure Scalability\r\nVirtualization, efficient power and cooling, cloud scale with automation, high density, and performance all support efficient data center growth.\r\n\r\nOperational Continuity\r\nThe design integrates hardware, NX-OS software features, and management to support zero-downtime environments.\r\n\r\nTransport Flexibility\r\nYou can incrementally and cost-effectively adopt new networking technologies.\r\n\r\nTechnologies that you can support include:\r\n\r\nRemote Integrated Service Engine (RISE)\r\nDynamic Fabric Automation (DFA)\r\nCisco Overlay Transport Virtualization (OTV)\r\nCisco FabricPath\r\nFibre Channel over Ethernet (FCoE)\r\nCisco Locator/ID Separation Protocol (LISP)\r\nCisco IOS Multiprotocol Label Switching (MPLS)\r\n\r\nInnovations\r\n\r\nNext-Generation Nexus 7700 M3-Series Modules: These feature-rich I/O modules deliver enhanced security, wire-rate performance with deep buffers, and high-capacity TCAMs for low-latency, highly secure, and scalable data centers.\r\n\r\nM3-Series 48-Port 1/10 GE Module\r\nM3-Series 24-Port 40 GE Module\r\nProgrammability with Cisco Open NX-OS: The Cisco Nexus 7000 family of switches offers an industry-leading, comprehensive set of programmable and automation tools for day-0 to day-N configuration and management. The 7000 Series offers standard, open, and programmable API interfaces for provisioning both control and data planes.\r\n\r\nFlexible customization through third-party application hosting capabilities such as Puppet, Chef, and Ansible\r\nUse of the Cisco NX-API for remote programmable access to the switch\r\nVisit the DevNet community for programmability resources.\r\n\r\nVirtual Topology System: Automate overlay provisioning for both virtual and physical workloads for faster application delivery.","shortDescription":"Cisco Nexus 7000 Series Switches create the network foundation for your next-generation Unified Fabric data center. Modular switches, including the Cisco Nexus 7000 and 7700 Series, deliver a comprehensive Cisco NX-OS feature set and open source programmable tools for software-defined network (SDN) deployments.","type":null,"isRoiCalculatorAvaliable":false,"isConfiguratorAvaliable":false,"bonus":100,"usingCount":5,"sellingCount":11,"discontinued":0,"rebateForPoc":0,"rebate":0,"seo":{"title":"Cisco Nexus 7000 Series Switches","keywords":"Cisco, Nexus, 7000, data, Series, center, with, NX-OS","description":"Build a Next-Generation Network\r\n\r\nCisco Nexus 7000 Series Switches create the network foundation for your next-generation Unified Fabric data center. Modular switches, including the Cisco Nexus 7000 and 7700 Series, deliver a comprehensive Cisco NX-OS feature","og:title":"Cisco Nexus 7000 Series Switches","og:description":"Build a Next-Generation Network\r\n\r\nCisco Nexus 7000 Series Switches create the network foundation for your next-generation Unified Fabric data center. Modular switches, including the Cisco Nexus 7000 and 7700 Series, deliver a comprehensive Cisco NX-OS feature","og:image":"https://old.roi4cio.com/fileadmin/user_upload/Kommutatory_Cisco_Nexus_serii_7000.jpg"},"eventUrl":"","translationId":412,"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"}],"characteristics":[],"concurentProducts":[],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":[],"implementations":[]}],"jobRoles":[],"organizationalFeatures":[],"complementaryCategories":[],"solutions":[],"materials":[],"useCases":[],"best_practices":[],"values":["Reduce Costs","Ensure Security and Business Continuity"],"implementations":[{"id":68,"title":"Cisco 7600 series router with control module for Cisco Catalyst 7600 series for modernization of the core of the information and computing network of the scientific center","url":"https://old.roi4cio.com/vnedrenija/vnedrenie/cisco-7600-series-router-with-control-module-for-cisco-catalyst-7600-series/"},{"id":1041,"title":"Cisco 7600 routers for Ukrainian provider","url":"https://old.roi4cio.com/vnedrenija/vnedrenie/cisco-7600-routers-for-ukrainian-provider/"}],"presenterCodeLng":"","productImplementations":[{"id":68,"title":"Cisco 7600 series router with control module for Cisco Catalyst 7600 series for modernization of the core of the information and computing network of the scientific center","description":"Description is not ready yet","alias":"cisco-7600-series-router-with-control-module-for-cisco-catalyst-7600-series","roi":0,"seo":{"title":"Cisco 7600 series router with control module for Cisco Catalyst 7600 series for modernization of the core of the information and computing network of the scientific center","keywords":"","description":"Description is not ready yet","og:title":"Cisco 7600 series router with control module for Cisco Catalyst 7600 series for modernization of the core of the information and computing network of the scientific center","og:description":"Description is not ready yet"},"deal_info":"","user":{},"supplier":{},"vendors":[{"id":170,"title":"Cisco","logoURL":"https://old.roi4cio.com/uploads/roi/company/Cisco_logo.png","alias":"cisco","address":"","roles":[],"description":"<span lang=\"en\">Cisco Systems is a global manufacturer of network equipment: routers, switches and servers, as well as software for data transmission on the Internet and corporate networks. 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