Opportunistic Media Access for Multirate Ad Hoc Networks

1. Opportunistic Media Access for Multirate Ad Hoc Networks B.Sadegahi, V.Kanodia, A.Sabharwal and E.Knightly Presented by Matti Raustia

2. Contents • WLAN • Rate Adaptation • ARF • RBAR • OAR • Simulation Results • Conclusion

3. 802.11 WLAN • Specified by IEEE • 802.11b (1999) • 2.4 GHz DSSS • Multirate: 1, 2, 5.5, 11 Mbit/s • Proprietary modes up to 22 Mbit/s • 802.11a • 5 GHz OFDM • Multirate: 6, 12, 24, 36, 48, 54 Mbit/s • 802.11g • 2.4 GHz OFDM, 2.4GHz DSSS • Compatible with 802.11b devices • Multirate: 802.11b data rates + OFDM data rates up to 54 Mbit/s

4. Why is Rate Adaptation Needed? • According to IEEE standards we can scale the data rate according to channel conditions • Radio channel conditions are changing if TX, RX or something between them is moving • this causes that maximum achievable data rate in the channel is changing also • if we can use higher data rate when channel is good we can increase the throughput • Higher data rates overall • More traffic or users • We must have some way to control the data rate adaptation

5. How to Implement It? • First we have to have some knowledge about the channel so we can adapt the data rate • 802.11 uses time division (TDMA/TDD) and radio channel is reciprocal • Physical layer (PHY) of destination or sender can measure the channel and inform MAC

6. Auto Rate Fallback (ARF) • ARF is the first commercial implementation that exploits multi-rate capability • Senders use history of previous transmission error rates to select future transmission rates • If no errors, increase the data rate • If errors, decrease the data rate • Achieves performance gain over plain 802.11

7. Receiver Based Auto Rate (RBAR) • Idea: Why not let the receiver decide which data rate to use? He knows the channel much better than sender because of RTS message • Well, due the CTS message the sender knows the channel also but then sender would have to signal the data rate used to the receiver • Physical Layer (PHY) of the receiver analysis the channel conditions from RTS message and inserts orders of data rate to the CTS message • Other nodes hear the CTS also and can adapt their NAV accordingly • Sender adapts the data rate • Performance gain over IEEE 802.11 and ARF

8. 802.11 with RBAR DIFS = Distributed InterFrame Spacing SIFS = Short InterFrame Spacing RTS = Ready to Send CTS = Clear to Send ACK = Acknowledge RSH = Reservation Sub- Header NAV = Network Allocation Vector

9. Opportunistic Auto Rate • Source sends Ready to Send (RTS) message at base date rate • Receiver’s PHY measures channel condition from it • Receiver sends Clear to Send (CTS) message to sender with orders to use specific data rate • Source sends as many packets that can be sent in base rate time window (for example 11 Mbit/s / 2 Mbit/s = 5 packets) • Time window is the same all the time regardless of channel conditions • Fairness

10. Fragmentation • Long packets can be fragmented according 802.11 • What if channel changes during transmission of long packet? • OAR receiver monitors channel conditions during transmission and if channel quality decreases, receiver can inform sender with additional RSH message to decrease data rate • What if sender doesn’t have enough packets in queue? • In this case OAR sender can revert to RBAR without throughput loss

11. RBAR and OAR: A Comparison • RBAR causes channel contention after each packet • It seems like the Node 2 doensn’t get any channel access at all...

12. Simulation results

13. Simulation results • OAR and RBAR have performance nearly independent from the velocity • Slow velocity -> large channel coherence times...

14. Conclusion • Nodes with good channel conditions are allowed to transmit multiple packets • OAR ensures that all the nodes get equal time share • fair • OAR obtains throughput gains up to 50 % if compared to RBAR • OAR method is simple

15. References • B.Sadegahi, V.Kanodia, A.Sabharwal and E.Knightly: Opportunistic Media Access for Multirate Ad Hoc Networks. MOBICOM’02