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|"Computer network types
by spatial scope
A wide area network (WAN) is a "telecommunications network or "computer network that extends over a large geographical distance. Wide area networks are often established with "leased telecommunication circuits.
Business, education and government entities use wide area networks to relay data among staff, students, clients, buyers, and suppliers from various locations across the world. In essence, this mode of telecommunication allows a business to effectively carry out its daily function regardless of location. The "Internet may be considered a WAN.
Related terms for other types of networks are "personal area networks (PANs), "local area networks (LANs), "campus area networks (CANs), or "metropolitan area networks (MANs) which are usually limited to a room, building, campus or specific metropolitan area respectively.
The textbook definition of a WAN is a computer network spanning regions, countries, or even the world. However, in terms of the application of computer "networking protocols and concepts, it may be best to view WANs as computer networking technologies used to transmit data over long distances, and between different LANs, MANs and other localised computer networking architectures. This distinction stems from the fact that common LAN technologies operating at lower layers of the "OSI model (such as the forms of "Ethernet or "Wi-Fi) are often designed for physically proximal networks, and thus cannot transmit data over tens, hundreds or even thousands of miles or kilometres.
WANs do not just necessarily connect physically disparate LANs. A CAN, for example, may have a localised backbone of a WAN technology, which connects different LANs within a campus. This could be to facilitate higher "bandwidth applications, or provide better functionality for users in the CAN.
WANs are used to connect LANs and other types of networks together, so that users and computers in one location can communicate with users and computers in other locations. Many WANs are built for one particular organization and are private. Others, built by "Internet service providers, provide connections from an organization's LAN to the Internet. WANs are often built using "leased lines. At each end of the leased line, a "router connects the LAN on one side with a second "router within the LAN on the other. Leased lines can be very expensive. Instead of using leased lines, WANs can also be built using less costly "circuit switching or "packet switching methods. Network "protocols including "TCP/IP deliver transport and addressing functions. Protocols including "Packet over SONET/SDH, "Multiprotocol Label Switching (MPLS), "Asynchronous Transfer Mode (ATM) and "Frame Relay are often used by service providers to deliver the links that are used in WANs. "X.25 was an important early WAN protocol, and is often considered to be the "grandfather" of Frame Relay as many of the underlying protocols and functions of "X.25 are still in use today (with upgrades) by Frame Relay.
Academic research into wide area networks can be broken down into three areas: "mathematical models, "network emulation and "network simulation.
Performance improvements are sometimes delivered via "wide area file services or "WAN optimization.
Many technologies are available for wide area network links. Examples include "circuit switched telephone lines, "radio wave transmission, and "optic fiber. New developments in technologies have successively increased transmission rates. In ca. 1960, a 110 bit/s (bits per second) line was normal on the edge of the WAN, while core links of 56 kbit/s to 64 kbit/s were considered fast. As of 2014, households are connected to the Internet with "Dial-Up, "ADSL, "Cable, "Wimax, "4G or "fiber The speeds that people can currently use range from 28.8 Kilobits per second through a "28K modem over a telephone connection to speeds as high as 100 Gigabits per second over an Ethernet "100GBaseY connection.
AT&T plans to start conducting trials in the year 2017 for businesses to use 400 Gigabit Ethernet. Researchers Robert Maher, Alex Alvarado, Domaniç Lavery & Polina Bayvel of University College London were able to increase networking speeds to 1.125 Terabits per second. Christos Santis, graduate student Scott Steger, Amnon Yariv, Martin and Eileen Summerfield developed a new laser that quadruples transfer speeds over fiber optic cabling. If you multiply 1.125 times 4 on your calculator (the amount of terabits per second achieved by University College of London researchers times the laser technology that quadruples transfer speeds over fiber optics developed by Caltech researchers) you get 4.5, and that means that with the two technologies combined that currently exist we could have 4.5 Terabit per second internet speeds available to the public sometime in the near future.