EECS 228a, Spring 2006 Shyam Parekh 802.16/WiMAX EECS 228a, Spring 2006 Shyam Parekh
References IEEE 802.16-2004 (802.16REVd) IEEE 802.16-2005 (802.16e) Intel’s Whitepapers, 2004 (http://www.intel.com/technology/itj/2004/volume08issue03/) “IEEE Standard 802.16: A Technical Overview of the WirelessMAN Air Interface for Broadband Wireless Access,” C. Eklund et al., IEEE Communication Magazine, June 2002 “Broadband Wireless Access with 802.16/WiMax: Current Performance Benchmarks and Future Potential,” A. Ghosh et al., IEEE Communication Magazine, Feb 2005 “Wireless Communication Standards: A Study of IEEE 802.11, 802.15, and 802.16,” T. Cooklev, 2004
Electromagnetic Spectrum Source: LBL
802.16 Standards History First standard based on proprietary implementations of DOCSIS/HFC architecture in wireless domain 802.16 (Dec 2001) Original fixed wireless broadband air Interface for 10 – 66 GHz: Line-of-sight only, Point-to-Multi-Point applications 802.16c (2002) 802.16a (Jan 2003) Extension for 2-11 GHz: Targeted for non-line-of-sight, Point-to-Multi-Point applications like “last mile” broadband access 802.16 Amendment WiMAX System Profiles 10 - 66 GHz 802.16REVd (802.16-2004) (Oct 2004) Adds WiMAX System Profiles and Errata for 2-11 GHz 802.16e (802.16-2005) (Dec 2005) MAC/PHY Enhancements to support subscribers moving at vehicular speeds
Applications of 802.16 Standards
802.16 Network Architecture
802.16 Network Architecture (2)
Scope of 802.16 Standards
Physical Layer Summary Designation Applicability MAC Duplexing WirelessMAN-SC 10-66 GHz Licensed Basic TDD, FDD, HFDD 2-11 GHz Licensed Basic, (ARQ), (STC), (AAS) TDD, FDD WirelessMAN-OFDM 2-11 GHz License-exempt Basic, (ARQ), (STC), (DFS), (MSH), (AAS) TDD WirelessMAN-OFDMA
Channel Characteristics 10-66 GHz Very weak multipath components (LOS is required) Rain attenuation is a major issue Single-carrier PHY 2-11 GHz Multipath NLOS Single and multi-carrier PHYs
Wireless Performance (as of 2003) Source: S. Viswanathan, Intel
OFDMA Subchannels A subset of subcarriers is grouped together to form a subchannel A transmitter is assigned one or more subchannels in DL direction (16 subchannels are supported in UL in OFDM PHY) Subchannels provide interference averaging benefits for aggressive frequency reuse systems
OFDM Basics Orthogonal Subcarriers Cyclic Prefix in Frequency Domain Cyclic Prefix in Time Domain
Equalizers are avoided in OFDM Narrow bandwidth long symbol times all significant multipaths arrive within a symbol time minimizing ISI no equalization low complexity Tx Signal Rx Signal Note: All signals & multipath over a useful symbol time are from the same symbol & add constructively (no ISI) time Cyclic Prefix Useful Symbol Time time Note: dashed lines represent multipath Source: Lucent
Tradeoffs of FFT size The FFT size determines the number of sub-carriers in the specified bandwidth Larger FFT sizes lead to narrower subcarriers and smaller inter-subcarrier spacing More susceptibility to ICI, particularly in high Doppler (Note: Doppler shift for 125 km/hr for operation at 3.5 GHz is v/λ = 35 m/sec/0.086 m = 408 Hz) Narrower subcarriers lead to longer symbol times less susceptibility to delay spread Smaller FFT sizes the opposite is true Source: Lucent
OFDMA Scalability Supports s wide range of frame sizes (2-20 ms) Source: Intel “Scalable OFDMA Physical Layer in IEEE 802.16 WirelessMAN”
Time Division Duplexing (TDD)
General Downlink Frame Structure Downlink Interval Usage Code (DIUC) indicates burst profile
General Uplink Frame Structure Uplink Interval Usage Code (UIUC) indicates burst profile
OFDMA TDD Frame Structure DL-MAP and UL-MAP indicate the current frame structure BS periodically broadcasts Downlink Channel Descriptor (DCD) and Uplink Channel Descriptor (UCD) messages to indicate burst profiles (modulation and FEC schemes)
Frame Structure – Another View
Network Entry Process
SDU and PDU
Connections 802.16/WiMAX is connection oriented For each direction, a connection identified with a 16 bit CID Each CID is associated with a Service Flow ID (SFID) that determines the QoS parameters for that CID
PDU Transmission Source: R. Marks (NIST) IEEE Presentation
QoS Mechanism
Generic MAC Frame
Generic MAC Header
Generic Bandwidth Request
Management Messages Management messages are broadcast or sent on three CIDs in each direction: Basic, Primary, and Secondary Uplink Channel Descriptor Downlink Channel Descriptor UL-MAP DL-MAP DSA-REQ DSA-RSP
Key Management Messages (1)
Key Management Messages (2)
Scheduling Types and QoS Parameters Unsolicited Grant Service (UGS) Max Sustained Traffic Rate, Maximum Latency, Tolerated Jitter Real-Time Polling Service (rtPS) Max Sustained Traffic Rate, Min Reserved Traffic Rate, Committed Burst Size, Maximum Latency, etc. Non-real-time Polling Service (nrtPS) Committed Information Rate, Maximum Information Rate Best Effort (BE) Maximum Information Rate Extended rtPS was introduced in 802.16e that combines UGS and rtPS: This has periodic unsolicited grants, but the grant size can be changed by request
Scheduling Classes
Advanced 802.16 Features Multiple Input and Multiple Output (MIMO) MIMO channel capacity is given by C = B log2 det(I + SNR.HH*T/N) where H is MxN channel matrix with M and N are receive and transmit antennas, resp. Hybrid-ARQ For faster ARQ, combines error correction and detection and makes use of previously received versions of a frame Adaptive Antenna System (AAS) Enables directed beams between BS and SSs
WiBro (Wireless Broadband) WiBro is an early large-scale deployment of 802.16 in South Korea (Dec 2005) Demonstrates 802.16 performance as compared to 3G/4G cellular alternatives 3 operators have been licensed by the government (each spending ~$1B)
WiMAX Opportunities There is a work opportunity to create/enhance 802.16/WiMAX network level simulation Contact sparekh@lucent.com Technical contributions characterizing 802.16 performance and network capacity are much needed