1. IEEE 802.11e Performance Evaluation
November 2003
IEEE e Performance Evaluation
Javier del Prado and Patrick Wienert
Philips
Javier del Prado et al. Philips

2. Outline Goal Overview of Protocols Evaluated Simulation Results
November 2003
Outline
Goal
Overview of Protocols Evaluated
Simulation Results
Conclusions
References
Javier del Prado et al. Philips

3. November 2003
Goal
Evaluate the Throughput Performance of IEEE e MAC protocols as a function of the Frame Size and the Number of Stations
Verify that the Usage Scenarios defined in are implementable
Javier del Prado et al. Philips

4. Overview of Protocols Evaluated
November 2003
Overview of Protocols Evaluated
Frame exchanges used in the simulation
Javier del Prado et al. Philips

5. Access Point has frames for Station
November 2003
DCF
Busy
Access Point has frames for Station
Access Point
Beacon t
Backoff
DIFS
Frame 1
Backoff
DIFS
Frame 2
Ack
SIFS
Beacon Interval. Typical value = 100 ms
Ack
SIFS
Wireless Station
Javier del Prado et al. Philips

6. (Reduces Backoff Overhead)
November 2003
EDCA
TXOP Bursting
(Reduces Backoff Overhead)
t < EDCA TXOP limit
Access Point
Beacon t
Busy
Backoff
AIFS
Frame 1
Frame 2
Ack
SIFS
Backoff
AIFS
Ack
SIFS
Wireless Station
Javier del Prado et al. Philips

7. EDCA with No ACK November 2003 t t Javier del Prado et al. Philips
t < EDCA TXOP limit
t < EDCA TXOP limit
Wireless Station
Busy
Backoff
AIFS
Frame 1
Frame 2
Frame 3
Backoff
AIFS
Frame 1
Frame 2
Frame 3
SIFS
SIFS
SIFS
SIFS t
Access Point t
Javier del Prado et al. Philips

8. (Reduces Poll and Ack Overheads)
November 2003
HCCA
UPLINK TXOP
DOWNLINK TXOP
Polled TXOP limit
Downlink TXOP limit
Beacon
Piggybacking
(Reduces Poll and Ack Overheads)
Access Point
Busy
Poll + Data
Ack
Ack
Data
Data
PIFS
SIFS
SIFS
PIFS
SIFS t
SIFS
SIFS
SIFS
Wireless Station
Data + Ack
Data
Ack t
Javier del Prado et al. Philips

9. HCCA with NO ACK November 2003 t t UPLINK TXOP DOWNLINK TXOP
Polled TXOP limit
Downlink TXOP limit
Beacon
Access Point
Busy
Poll + Data
Data
Data
Data
PIFS
SIFS
PIFS t
SIFS
SIFS
SIFS
SIFS
Wireless Station
Data
Data
Data t
Javier del Prado et al. Philips

10. November 2003
Simulation Results
Javier del Prado et al. Philips

11. BriarLAN 10.0 Simulator Based on OPNET 10.0 PL2 (October 2003)
November 2003
BriarLAN 10.0 Simulator
Based on OPNET 10.0 PL2 (October 2003)
Model Library:
Functionality
Full Legacy MAC (DCF + PCF)
Most of e Implementation (Draft 5.0)
New Frame Format
EDCA
EDCA TXOP Bursting
Polled TXOP Request
Polled TXOP Bursting
No ACK Policy
DLP
Javier del Prado et al. Philips

12. Throughput vs. Frame Size
November 2003
Throughput vs. Frame Size
Simulation Scenario:
There are two senders and two receivers
The senders generate at an infinite rate, L-byte long data frames
The frames are not fragmented
The channel is error free
The beacon interval is 100 ms
The underlying PHY layer is a
The Data transmission rate is 54 Mb/s
The ACK transmission rate is 24 Mb/s
In EDCA simulations AC_VO parameters are used
For HCCA
The Simple Scheduler defined in e D5.0 is used
CFP is 90 ms
During CP, wireless STAs use AC_VO
Five frames can be transmitted within a TXOP.
Javier del Prado et al. Philips

13. Throughput vs. Frame Size
November 2003
Throughput vs. Frame Size
Javier del Prado et al. Philips

14. Throughput vs. Number of STAs
November 2003
Throughput vs. Number of STAs
6 different homogeneous scenarios
All stations in each scenario run the same MAC protocol, with same access parameters
Load
Each STA generates 4 Mb/s of traffic
Packet size of 1500 bytes
EDCA
AC default parameters
HCCA
Simple scheduler with TXOPs of 5 ms
Javier del Prado et al. Philips

15. Throughput vs. Number of STAs
November 2003
Throughput vs. Number of STAs
Javier del Prado et al. Philips

16. Simulation Results for Usage Scenario 1
November 2003
Simulation Results for Usage Scenario 1
Reference:
Javier del Prado et al. Philips

17. Traffic Generation As defined in 11-03-802-01
November 2003
Traffic Generation
As defined in
With the Application parameters as shown in the Applications table
Added VoD control channel for STA4
STA11 is not simulated – Video Gaming Controller
0.5 Mb/s with 50 bytes packets?  1250 packets/sec?
Delay Limit of 4 ms?
Javier del Prado et al. Philips

18. November 2003
Application Set-Up
Javier del Prado et al. Philips

19. November 2003
TCP Parameters
Javier del Prado et al. Philips

20. November 2003
TCP Parameters
Javier del Prado et al. Philips

21. November 2003
WLAN Parameters
Javier del Prado et al. Philips

22. Internet Streaming + MP3 Audio
November 2003
EDCA Parameters
Default Parameters defined in e D5.0
Application
EDCA AC
HDTV
AC_VI
SDTV
Internet File
AC_BE
VoIP
AC_VO
Internet Streaming + MP3 Audio
Local File Transfer
Video Phone
We have not tried to optimize EDCA
Javier del Prado et al. Philips

23. HCCA Parameters Used the Simple Scheduler in 802.11e D5.0
November 2003
HCCA Parameters
Used the Simple Scheduler in e D5.0
Polling Interval of 30 ms
Minimum Delay Limit of all applications in Scenario 1
We have not tried to optimize Scheduling Algorithm
Javier del Prado et al. Philips

24. PHY Layer 802.11a frame format and IFSs Error free channel
November 2003
PHY Layer
802.11a frame format and IFSs
Error free channel
All STAs transmit data at 216 Mb/s
Control and Management Frames at 24 Mb/s
Javier del Prado et al. Philips

25. November 2003
Javier del Prado et al. Philips

26. DCF Simulation Results
November 2003
DCF Simulation Results
Wireless LAN data dropped
Data is only dropped at the AP
The AP has the same priority than other STAs
Same probability to access the medium
But the AP carries about 50 Mb/s
Javier del Prado et al. Philips

27. EDCA simulation results
November 2003
EDCA simulation results
Wireless LAN Throughput
Wireless LAN Data Dropped
Need to calculate PLR from these results + delay curves
Javier del Prado et al. Philips

28. EDCA simulation results
November 2003
EDCA simulation results
SDTV/HDTV End-to-End Delay
Javier del Prado et al. Philips

29. EDCA simulation results
November 2003
EDCA simulation results
VoIP End-to-End Delay UPLINK
Javier del Prado et al. Philips

30. EDCA simulation results
November 2003
EDCA simulation results
VoIP End-to-End Delay DOWNLINK
Javier del Prado et al. Philips

31. EDCA simulation results
November 2003
EDCA simulation results
TCP Throughput
Javier del Prado et al. Philips

32. HCCA simulation results
November 2003
HCCA simulation results
Wireless LAN Throughput
Wireless LAN Data Dropped
Most of data dropped is TCP traffic
Javier del Prado et al. Philips

33. HCCA simulation results
November 2003
HCCA simulation results
HDTV/SDTV End to End Delay
CDF of HDTV/SDTV End to End Delay
Javier del Prado et al. Philips

34. HCCA simulation results
November 2003
HCCA simulation results
VoIP End-to-End Delay UPLINK
Javier del Prado et al. Philips

35. HCCA simulation results
November 2003
HCCA simulation results
TCP Throughput
Javier del Prado et al. Philips

36. November 2003
Conclusions
Evaluation of the IEEE e MAC Throughput as a function of frame size and number of stations
IEEE e MAC can achieve high efficiency for large frame sizes
Up to 90%
Between 55 and 80% for a 1500 bytes long frame
HCCA throughput is independent of number of Stations
Javier del Prado et al. Philips

37. Conclusions Simulation of Usage Scenario I
November 2003
Conclusions
Simulation of Usage Scenario I
Both EDCA and HCCA guarantee the required PLR in this simulation scenario
There is some data dropped, but given low delay achieved, we can play with the buffer sizes
For a 216 Mb/s PHY rate, the network is close to its limit
We need to include Channel Errors
Do we need to relax the Usage Scenarios definition?
Specially for applications with small packet sizes and low delay limit
Javier del Prado et al. Philips

38. November 2003
References
[1] Sunghyun Choi, Javier del Prado, Stefan Mangold, and Sai Shankar, “IEEE e Contention-Based Channel Access (EDCF) Performance Evaluation,” in Proc. IEEE ICC’03, Anchorage, Alaska, USA, May 2003
[2] Javier del Prado, Sunghyun Choi and Sai Shankar "IEEE e EDCF: a QoS Solution for WLAN"  2nd New York Metro Area Networking Workshop, 2002
[3] Javier del Prado and Sunghyun Choi, “Link Adaptation Strategy for IEEE WLAN via Received Signal Strength Measurement,” in Proc. IEEE ICC’03, Anchorage, Alaska, USA, May 2003.
[4] S. Mangold, G. Hiertz, B. Walke, “IEEE e Wireless LAN - Resource Sharing with Contention Based Medium Access,” in PIMRC 2003
[5] S. Mangold, “Analysis of IEEE e and Application of Game Models for Support of Quality-of-Service in Coexisting Wireless Networks PhD Thesis,” June 2003
[6] S. Mangold, S. Choi, G. Hiertz, O. Klein, B. Walke, “Analysis of IEEE e for QoS Support in Wireless LANs,” Communications Magazine, Dec 2003
[7] S. Mangold, S. Choi, P. May, O. Klein, G. Hiertz, L. Stibor “IEEE e Wireless LAN for Quality of Service,” European Wireless 2002
Javier del Prado et al. Philips

39. November 2003
Backup Slides
Javier del Prado et al. Philips

40. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 100 bytes packet and 11a PHY
Javier del Prado et al. Philips

41. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 100 bytes packet and 11a PHY
Javier del Prado et al. Philips

42. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 1500 bytes packet and 11a PHY
Javier del Prado et al. Philips

43. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 100 bytes packet and “11n” PHY at 216 Mb/s
Javier del Prado et al. Philips

44. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 1500 bytes packet and “11n” PHY at 216 Mb/s
Javier del Prado et al. Philips

45. Where are the overheads coming from?
November 2003
Where are the overheads coming from?
For a 1500 bytes packet and “11n” PHY at 216 Mb/s
Javier del Prado et al. Philips