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WiMAX

WiMAX. Emerging Technologies. Current Scenario. Think about how you access the Internet today. There are basically three different options: Broadband access - In your home, you have either a DSL or cable modem. At the office, your company may be using a T1 or a T3 line.

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WiMAX

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  1. WiMAX Emerging Technologies

  2. Current Scenario • Think about how you access the Internet today. There are basically three different options: • Broadband access - In your home, you have either a DSL or cable modem. At the office, your company may be using a T1 or a T3 line. • WiFi access - In your home, you may have set up a WiFi router that lets you surf the Web while you lounge with your laptop. On the road, you can find WiFi hot spots in restaurants, hotels, coffee shops and libraries. • Dial-up access - If you are still using dial-up, chances are that either broadband access is not available, or you think that broadband access is too expensive.

  3. Current Scenario • The main problems with broadband access are that it is pretty expensive and it doesn't reach all areas. The main problem with WiFi access is that hot spots are very small, so coverage is sparse. • What if there were a new technology that solved all of these problems? This new technology would provide: • The high speed of broadband service. • Wireless rather than wired access, so it would be a lot less expensive than cable or DSL and much easier to extend to suburban and rural areas. • Broad coverage like the cell phone network instead of small WiFi hotspots.

  4. Wireless Broadband • This system is actually coming into being right now, and it is called WiMAX. WiMAX is short for Worldwide Interoperability for Microwave Access, and it also goes by the IEEE name 802.16. • Also known as Wireless Metropolitan Area Network (Wireless MAN). • Offers an alternative to high bandwidth wired access networks like fiber optic, cable modems and DSL. • Provides network access to buildings through exterior antennas communicating with radio base stations. • Networks can be created in just weeks by deploying a small number of base stations on buildings or poles to create high capacity wireless access systems.

  5. WiMax Vs. WiFi • WiMAX operates on the same general principles as WiFi - it sends data from one computer to another via Radio signals. • A computer (either a desktop or a laptop) equipped with WiMAX would receive data from the WiMAX transmitting station, probably using encrypted • data keys to prevent unauthorized users from stealing access. • The fastest WiFi connection can transmit up to 54 megabits per second under optimal conditions. WiMAX should be able to handle up to 70 megabits per second. • Even once that 70 megabits is split up between several dozen businesses or a few hundred home users, it will provide at least the equivalent of cable-modem transfer rates to each user.

  6. WiMax Vs. WiFi • The biggest difference isn't speed; it's distance. WiMAX outdistances WiFi by miles. WiFi's range is about 100 feet (30 m). WiMAX will blanket a radius of 30 miles (50 km) with wireless access. • The increased range is due to the frequencies used and the power of the • transmitter. • Of course, at that distance, terrain, weather and large buildings will act to reduce the maximum range in some circumstances, but the potential is there to cover huge tracts of land. • WiMax is not designed to clash with WiFi, but to coexist with it. • WiMax specifications also provides much better facilities than WiFi, providing higher bandwidth and high data security by the use of enhanced encryption schemes.

  7. WiMAX is not Wi-Fi

  8. Overview of IEEE 802.16

  9. Sub-standards of IEEE 802.16 • IEEE 802.16.1 - Air interface for 10 to 66 GHz • IEEE 802.16.2 - Coexistence of broadband wireless access systems • IEEE 802.16.3 - Air interface for licensed frequencies, 2 to 11 GHz

  10. Basics of IEEE 802.16 IEEE 802.16 standards are concerned with the air interface between a subscriber’s transceiver station and a base transceiver station • The Physical Layer • MAC Layer • Convergence Layer

  11. IEEE 802.16 Protocol Architecture

  12. Physical Layer • Specifies the frequency band, the modulation scheme, error-correction techniques, synchronization between transmitter and receiver, data rate and the multiplexing structure • Both TDD and FDD alternatives support adaptive burst profiles in which modulation and coding options may be dynamically assigned on a burst-by-burst basis • Three physical layer for services: Wireless MAN-SC2, Wireless MAN-OFDM and Wireless MAN-OFDMA

  13. Medium Access Control Layer • Designed for point-to-multipoint broadband wireless access • Addresses the need for very high bit rates, both uplink (to the base station) and downlink (from the base station) • Services like multimedia and voice can run as 802.16 MAC is equipped to accommodate both continuous and bursty traffic

  14. Convergence Layer • Provides functions specific to the service being provided • Bearer services include digital audio/video multicast, digital telephony, ATM, Internet access, wireless trunks in telephone networks and frame relay

  15. Reference Network Model • The IEEE 802.16e-2005 standard provides the air interface for WiMAX but does not define the full end-to-end WiMAX network. The WiMAX Forum's Network Working Group (NWG), is responsible for developing the end-to-end network requirements, architecture, and protocols for WiMAX, using IEEE 802.16e-2005 as the air interface. • The WiMAX NWG has developed a network reference model to serve as an architecture framework for WiMAX deployments and to ensure interoperability among various WiMAX equipment and operators. • The network reference model envisions a unified network architecture for supporting fixed, nomadic, and mobile deployments and is based on an IP service model.

  16. Reference Network Model • The overall network may be logically divided into three parts: 1. Mobile Stations (MS) used by the end user to access the network. 2. The access service network (ASN), which comprises one or more base stations and one or more ASN gateways that form the radio access network at the edge. 3. Connectivity service network (CSN), which provides IP connectivity and all the IP core network functions.

  17. Reference Network Model

  18. Reference Network Model • The network reference model developed by the WiMAX Forum NWG defines a number of functional entities and interfaces between those entities. Fig below shows some of the more important functional entities. 1) Base station (BS): The BS is responsible for providing the air interface to the MS. Additional functions that may be part of the BS are micromobility management functions, such as handoff triggering and tunnel establishment, radio resource management, QoS policy enforcement, traffic classification, DHCP (Dynamic Host Control Protocol) proxy, key management, session management, and multicast group management.

  19. Reference Network Model 2) Access service network gateway (ASN-GW): The ASN gateway typically acts as a layer 2 traffic aggregation point within an ASN. Additional functions that may be part of the ASN gateway include intra-ASN location management and paging, radio resource management and admission control, caching of subscriber profiles and encryption keys, AAA client functionality, establishment and management of mobility tunnel with base stations, QoS and policy enforcement, foreign agent functionality for mobile IP, and routing to the selected CSN.

  20. Reference Network Model 3) Connectivity service network (CSN): The CSN provides connectivity to the Internet, ASP, other public networks, and corporate networks. The CSN is owned by the NSP and includes AAA servers that support authentication for the devices, users, and specific services. The CSN also provides per user policy management of QoS and security. The CSN is also responsible for IP address management, support for roaming between different NSPs, location management between ASNs, and mobility and roaming between ASNs.

  21. Advanced Features of WiMAX • An important and very challenging function of the WiMAX system is the support of various advanced antenna techniques, which are essential to provide high spectral efficiency, capacity, system performance, and reliability. • Two Type of Services: WiMAX can provide two forms of wireless service: 1) Non-line-of-sight: service is a WiFi sort of service. Here a small antenna on your computer connects to the WiMAX tower. In this mode, WiMAX uses a lower frequency range -- 2 GHz to 11 GHz (similar to WiFi). 2) Line-of-sight: service, where a fixed dish antenna points straight at the WiMAX tower from a rooftop or pole. The line-of-sight connection is stronger and more stable, so it's able to send a lot of data with fewer errors. Line-of-sight transmissions use higher frequencies, with ranges reaching a possible 66 GHz.

  22. Advanced Features of WiMAX • Very high peak data rates: WiMAX is capable of supporting very high peak data rates. In fact, the peak PHY data rate can be as high as 74Mbps when operating using a 20MHz wide spectrum. More typically, using a 10MHz spectrum operating using TDD scheme with a 3:1 downlink-to-uplink ratio, the peak PHY data rate is about 25Mbps and 6.7Mbps for the downlink and the uplink, respectively.

  23. Advanced Features of WiMAX • Scalable bandwidth and data rate support: WiMAX has a scalable physical-layer architecture that allows for the data rate to scale easily with available channel bandwidth. For example, a WiMAX system may use 128, 512, or 1,048-bit FFTs (fast fourier transforms) based on whether the channel bandwidth is 1.25MHz, 5MHz, or 10MHz, respectively. This scaling may be done dynamically to support user roaming across different networks that may have different bandwidth allocations.

  24. Advanced Features of WiMAX • Quality-of-service support: The WiMAX MAC layer has a connection-oriented architecture that is designed to support a variety of applications, including voice and multimedia services. WiMAX system offers support for constant bit rate, variable bit rate, real-time, and non-real-time traffic flows, in addition to best-effort data traffic. WiMAX MAC is designed to support a large number of users, with multiple connections per terminal, each with its own QoS requirement.

  25. Advanced Features of WiMAX • Robust security: WiMAX supports strong encryption, using Advanced Encryption Standard (AES), and has a robust privacy and key-management protocol. The system also offers a very flexible authentication architecture based on Extensible Authentication Protocol (EAP), which allows for a variety of user credentials, including username/password, digital certificates, and smart cards. • Support for mobility: The mobile WiMAX variant of the system has mechanisms to support secure seamless handovers for delay-tolerant full-mobility applications, such as VoIP.

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