Wireless Metropolitan Area Networks (WMANs) using WiMAX.

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Presentation transcript:

Wireless Metropolitan Area Networks (WMANs) using WiMAX

Introduction The acronym WiMAX stands for “Worldwide Interoperability for Microwave Access”. It is based on IEEE standard. IEEE is the IEEE standard for Wireless Metropolitan Area Network (Wireless MAN). It specifies the air interface for fixed, portable, and mobile broadband wireless access (BWA) systems supporting multimedia services.

Introduction WiMAX aims to provide wireless broadband services with a target range of up to 31 miles at a transmission rate exceeding 100 Mbps. It is also to provide a wireless alternative to cable, DSL and T1/E1 for last mile access. The term IEEE and WIMAX are used interchangeably. WiMAX is to IEEE what Wi-Fi is to IEEE

Overview of the IEEE Standard Designed for point-to-point (PTP) and point- to-multipoint (PTM) topologies Mainly deployed for point to multipoint topologies. It also support mesh topologies. IEEE has three major versions; – , – and –

IEEE Addresses fixed line of sight connections and operates in the licensed frequency range between 10 GHz and 66 GHz. At these high frequency range there are more available bandwidth and reduced risk of interference. Has a maximum coverage of 5km.

IEEE (802.16d) Designed to operate in lower frequency range; 2-11 GHz. Support Non-line of sight (NLOS) operation. Operates in both licensed (3.5 GHz) and unlicensed (5.8 GHz). Operates with a range of up to 50km and data rates of up to 75Mbps. It is the most supported version of the standard by vendors.

IEEE (802.16e) Support mobility and will standardize networking between fixed base stations and mobile devices. Would enable high-speed signal handoffs necessary for communications with users moving at vehicular speeds which is below 100km/h. It will provide a symmetric (up and down) bit rates of 70Mbps. Operate in the frequency range between 2-6 GHz.

IEEE m To provide an advanced air interface for operation in licensed bands. The purpose of IEEE m is to provide performance improvements necessary to support future advanced service and applications

IEEE m Operating frequencies: less than 6 GHz Operating bandwidths: 5to 40MHz. Duplex schemes: IEEE m supports both TDD and FDD operational modes. – The FDD mode supports both full-duplex and half- duplex MS operation. – In TDD mode, the downlink (DL)/uplink (UL) ratio should be adjustable. – In FDD mode, the UL and the DL channel bandwidths may be different and should be configurable

IEEE m Support for advanced antenna techniques: – For the BS, a minimum of two transmit and two receive antennas shall be supported. – For the MS, a minimum of one transmit and two received antenna shall be supported. – IEEE m shall support MIMO, beamforming operation or other advanced antenna techniques.

IEEE m Support for government mandates and public safety: – IEEE m shall be able to support public- safety first responders, military and emergency services such as call-prioritization, preemption, and push-to-talk. – It shall support regional regulatory requirements, such as Emergency Services and – Communications Assistance for Law Enforcement Act (CALEA).

Applications To provide a wireless alternative to cable, DSL and T1/E1 for last mile access especially in areas where wire broadband access are absent. Serves as E1/T1 replacements for small and medium size businesses. Provide residential ‘wireless DSL’ for broadband Internet at home. It can be used as wireless backhaul for Wi-Fi hotspot and cellular companies. Operators/carriers can use it as a backup backbone. It can be used in disaster recovery scenes where the wired networks have broken down.

MAC Layer It is connection oriented and supports quality of service. It uses a slotted TDMA protocol scheduled by the base terminal station to allocate capacity to subscribers. Supports both Time Division Duplex (TDD) and Frequency Division Duplex (FDD) and, also Half Duplex-FDD. Supports quality of service (QoS) for stations through adaptive allocation of the uplink and downlink traffic. It also supports different transport technologies such as IPv4, IPv6, Ethernet, Asynchronous Transfer Mode (ATM) and any future protocol not yet developed.

MAC Layer

The IEEE MAC protocol supports point- to-multipoint broadband wireless access. It allows very high bit rates in the range of 3.5–0 MHz in both the forward and reverse links, at the same time allowing hundreds of terminals per channel that may potentially be shared by multiple end-users.

MAC Layer Must support a variety of backhaul requirements, including both ATM and packet-based protocols. Convergence sublayers are used to map the transport-layer–specific traffic to a MAC and offers features such as payload header suppression, packing, and fragmentation; the convergence sublayers and MAC work together in a form that is often more efficient than the original transport mechanism.

MAC Layer MAC includes a privacy sublayer; this provides authentication of network access, thereby avoiding theft of service and providing key exchange andencryptio n for data privacy.

MAC Layer Connection-oriented Supports difficult user environments High bandwidth, hundreds of users per channel For variable Continuous and burst traffic Very efficient use of spectrum Protocol-Independent core (ATM, IP, Ethernet, …) Balances between stability of contentionless and efficiency of contention-based operation Negotiate the burst profile between sender and receiver Flexible QoS offerings Supports multiple PHYs

Protocol Stack Packet convergence Sublayer (PCS) ATMpacketSSCS (security sublayer )

MAC Reference Model Convergence Sublayer (CS) – Mapping external network data into MAC SDU Classifying external network SDU Associating to MAC connection ID Payload header suppression Common Part Sublayer (CPS) – Core MAC functionality System access Bandwidth allocation Connection establishment Connection maintenance Security Sublayer – Authentication – Security key exchange – Encryption PHY – Multiple sections Each appropriate to a frequency range and application

Service Specific Convergence Sublayer (SSCS) The CS performs the following functions: – accepting – accepting higher-layer PDUs from the higher layer classification – performing classification of higher-layer PDUs – processing – processing (if required) the higher-layer PDUs based on the classification – delivering – delivering CS PDUs to the appropriate MAC SAP – receiving – receiving CS PDUs from the peer entity Currently, two CS specifications are provided – Asyncronous Transfer Mode (ATM) CS – Packet CS Such as IP, PPP, Ethernet, etc., Such as IP, PPP, Ethernet, etc.,

MPDU format MAC PDU formats Connections are identified by a 16-bit CID. HT=0 HT=1 Bandwidth Request Generic CRC capability is mandatory for SCa, OFDM and OFDMA PHY layers 6 octets

Generic MAC Header

Type encodings (in Generic Header) Bit mapping Type bits

Bandwidth Request MAC Header 000 : incremental (BS adds the needed quantity of CID) 001 : aggregate (BS replaces the needed quantity of CID)

Transmission of MAC PDUs The IEEE MAC supports various higher layer protocols such as ATM or IP. Incoming MAC SDUs from corresponding convergence sublayers are formatted according to the MAC PDU format, possibly with fragmentation and/or packing. After traversing the airlink, MAC PDUs are reconstructed back into the original MAC SDUs so that the format modifications performed by the MAC layer protocol are transparent to the receiving entity.

Transmission of MAC PDUs IEEE takes advantage of packing and fragmentation processes, and their effectiveness, flexibility, and efficiency are maximized by appropriate bandwidth allocation. Fragmentation is the process by which a MAC SDU is divided into one or more MAC SDU fragments. Packing is the process by which multiple MAC SDUs are packed into a single MAC PDU payload. Both processes may be initiated by either a BS for a DL or for a SS for an UL connection. IEEE allows simultaneous fragmentation and packing for efficient use of the bandwidth.

PHY Support and Frame Structure Supports both TDD and FDD. In FDD, both continuous and burst DLs are possible. Continuous DLs allow for certain robustness enhancement techniques, such as interleaving. Burst DLs (either FDD or TDD) allow the use of more advanced robustness and capacity enhancement techniques such as – subscriber-level adaptive burst profiling – advanced antenna systems.

PHY Support and Frame Structure TheMAC builds the DL subframe starting with a frame control section containing the DL-MAP (downlink MAP) and UL-MAP (uplink map) messages. These indicate PHY transitions on the DL as well as bandwidth allocations and burst profiles on the UP. The DL-MAP is always applicable to the current frame and is always at least two FEC blocks long. To allow adequate processing time, the first PHY transition is expressed in the first FEC block. In both TDD and FDD systems, the UL-MAP provides allocations starting no later than the next DL frame. The ULMAP can, however, start allocating in the current frame, as long as processing times and round-trip delays are observed.

Radio Link Control RLC control – transition of burst profile – power level – ranging BS broadcast RLC begins with periodic BS broadcast of the burst profiles that have been chosen for the uplink and downlink rain regionequipment capabilities – according to rain region and equipment capabilities. Burst profiles for the downlink/uplink are each tagged with aDownlink/Uplink Interval Usage Code (DIUC/UIUC) Burst profiles for the downlink/uplink are each tagged with a Downlink/Uplink Interval Usage Code (DIUC/UIUC).

Ranging and Power Control power levelingrangingranging request (RNG-REQ) messagesinitial maintenance windows During initialization, the SS performs initial power leveling and ranging using ranging request (RNG-REQ) messages transmitted in initial maintenance windows. ranging response (RNG-RSP) messages The adjustments to the SS’s transmit time advance, as well as power adjustments, are returned to the SS in ranging response (RNG-RSP) messages. RNG-RSP For ongoing ranging and power adjustments, the BS may transmit unsolicited RNG-RSP messages commanding the SS to adjust its power or timing. – It is not included in burst profile

Burst Profile Set of parameters that describe the uplink or downlink transmission properties associated with an interval usage code (IUC). The burst profile to use for any uplink transmission is defined by the Uplink Interval Usage Code (UIUC). – Each UIUC is mapped to a burst profile in the UCD message Each profile contains parameters such as a)modulation type b)forward error correction (FEC) type c)preamble length d)guard times

Burst Profile If the received CINR goes outside of the allowed operating region, the SS requests a change to a new burst profile using one of two methods granted – If the SS has been granted uplink bandwidth, it shall send a DBPC-REQ message in that allocation. The BS responds with a DBPC-RSP message. grant is not available – If grant is not available and the SS requires a more robust burst profile on the downlink, it shall send a RNG-REQ message in an Initial Ranging interval. – Note : using the Basic CID of the SS

Channel Acquisition Upon installation, SS begins scanning its frequency list to find an operating channel. It may be programmed to register with one specific BS, referring to a programmable BS ID broadcast by each. After deciding on which channel or channel pair to start communicating, the SS tries to synchronize to the DL transmission by detecting the periodic frame preambles. Once the physical layer is synchronized, the SS looks for periodic DCD (DL channel descriptor) and UCD (UL channel descriptor) broadcast messages that enable the SS to learn the modulation and FEC schemes used on the carrier.

IP Connectivity After registration, the SS acquires an IP address via the DHCP and establishes the time of day via the Internet time protocol. The DHCP server also provides the address of the TFTP server from which the SS can request a configuration file. This file provides a standard interface for providing vendor-specific configuration information.