Is the MAC sufficient for wireless high speed mesh LANs?

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Presentation transcript:

Is the 802.11 MAC sufficient for wireless high speed mesh LANs? May 2004 doc.: IEEE 802.11-02/xxxr0 May 2004 Is the 802.11 MAC sufficient for wireless high speed mesh LANs? Guido R. Hiertz, Lothar Stibor ComNets Chair of Communication Networks Aachen University Germany Jörg Habetha Philips Research Aachen Guido R. Hiertz, ComNets, Aachen University Guido R. Hiertz, ComNets, Aachen University

802.11 Basics Fixed interframe spaces (IFSs) Multiple PHY modes May 2004 doc.: IEEE 802.11-02/xxxr0 May 2004 802.11 Basics Fixed interframe spaces (IFSs) aSlot, SIFS All IFS others are sums of the above Multiple PHY modes E.g. 802.11a, 802.11b, 802.11g IFS constant for all PHY modes within same standard 802.11 relies here on Guido R. Hiertz, ComNets, Aachen University Guido R. Hiertz, ComNets, Aachen University

Basic calculations Simple scenario May 2004 Basic calculations Simple scenario One receiving station, one transmitting station Backoff duration equal to DIFS + 7.5*aSlot Error free wireless medium Guido R. Hiertz, ComNets, Aachen University

PHY efficiency 802.11a BPSK ½ Highly efficient May 2004 Guido R. Hiertz, ComNets, Aachen University

IFS limiting throughput May 2004 IFS limiting throughput OFDM PHY IFS according to 802.11a Assuming infinite PHY speed Guido R. Hiertz, ComNets, Aachen University

Assuming new PHY OFDM based Preamble = 12µs Header = 3µs tSYM = 3µs May 2004 Assuming new PHY OFDM based Preamble = 12µs Header = 3µs tSYM = 3µs aSlot = 4µs SIFS = 8µs 1024Mb/s PHY Guido R. Hiertz, ComNets, Aachen University

802.15.3a PHY OFDM based Preamble = 9.375µs Header = 2.188µs May 2004 802.15.3a PHY OFDM based Preamble = 9.375µs Header = 2.188µs tSYM = 312.5ns aSlot = 10µs SIFS = 10µs 200Mb/s PHY Guido R. Hiertz, ComNets, Aachen University

Performance problems Static overhead (e.g. OFDM) Protocol overhead May 2004 Performance problems Static overhead (e.g. OFDM) Independent of PHY speed (IFS etc.) Protocol overhead One ACK per one DATA frame 802.11e Block ACK very important to increase efficiency! Often transceiver turnaround Duration limited by hardware Constant preamble duration (OFDM) Can be become quite large compared to DATA Guido R. Hiertz, ComNets, Aachen University

Design issues for future MAC May 2004 Design issues for future MAC Idle channel is unused capacity Develop collision free MAC Avoid signaling for channel competition Piggyback additional information Use all available information Channel busy histogram (11-03/340r1a) Listen to neighbors QoS sensitive traffic may be “predictable” RTS but no CTS reception enables parallel transmission Guido R. Hiertz, ComNets, Aachen University

MAC design for high speed PHY May 2004 MAC design for high speed PHY Higher data rate → lower reception range Much bandwidth at high frequencies High attenuation, especially walls etc. Avoid small frames Concatenate frames Multiplex data Interference range determined by transmission power Regardless of PHY mode Incremental redundancy Always highest PHY Combine retransmitted & failed frame Guido R. Hiertz, ComNets, Aachen University

MAC regarding high attenuation May 2004 MAC regarding high attenuation Use attenuation to the benefit Spatial reuse possible Multi hop support needed High speed links with limited range Guido R. Hiertz, ComNets, Aachen University

Multi hop MAC issues Avoid hidden station problem May 2004 Multi hop MAC issues Avoid hidden station problem Avoid “Neighborhood capture” (11-01/596r1) Multiplex data on streams Avoid separate transmissions on same route Multiplex Data at forwarder Guido R. Hiertz, ComNets, Aachen University

Multi hop needs routing May 2004 Multi hop needs routing No information exchange between layers MAC layer routing instead L3 routing New routing aware of PHY mode Transmission power Interference level, etc. Guido R. Hiertz, ComNets, Aachen University

MAC regarding higher layers May 2004 MAC regarding higher layers WLAN drawbacks on TCP TCP transmission window MAC retransmissions Terminate TCP at AP Possible? Connection tracking? How to replace TCP on wireless link? WLAN aware of applications? VoIP Discard than retransmit Concatenation of frames Guido R. Hiertz, ComNets, Aachen University

Conclusions 802.11 MAC worked very well Future WLAN will need new MAC May 2004 Conclusions 802.11 MAC worked very well Highly efficient at low speed PHY Drawbacks at high speed Today’s “ethernet” (802.3) is switched WLAN is different Future WLAN will need new MAC Support for multi hop, MAC routing Increased efficiency Avoid “legacy” backoff Guido R. Hiertz, ComNets, Aachen University

Thank you for you attention May 2004 Thank you for you attention hiertz@ieee.org Guido R. Hiertz, ComNets, Aachen University