Download:
by Hongqiang Zhai, Student Member, Yuguang Fang, Senior Member
IEEE Transaction on Wireless Communications
http://winet.ece.ufl.edu/~zhq/tw05.pdf
Add To MetaCart
Abstract:
Abstract—This paper studies an important problem in the IEEE 802.11 distributed coordination function (DCF)-based wireless local area network (WLAN): how well can the network support quality of service (QoS). Specifically, this paper analyzes the network’s performance in terms of maximum protocol capacity or throughput, delay, and packet loss rate. Although the performance of the 802.11 protocol, such as throughput or delay, has been extensively studied in the saturated case, it is demonstrated that maximum protocol capacity can only be achieved in the nonsaturated case and is almost independent of the number of active nodes. By analyzing packet delay, consisting of medium access control (MAC) service time and waiting time, accurate estimates were derived for delay and delay variation when the throughput increases from zero to the maximum value. Packet loss rate is also given for the nonsaturated case. Furthermore, it is shown that the channel busyness ratio provides precise and robust information about the current network status, which can be utilized to facilitate QoS provisioning. The authors have conducted a comprehensive simulation study to verify their analytical results and to tune the 802.11 to work at the optimal point with maximum throughput and low delay and packet loss rate. The simulation results show that by controlling the total traffic rate, the original 802.11 protocol can support strict QoS requirements, such as those required by voice over Internet protocol (VoIP) or streaming video, and at the same time achieve high channel utilization. Index Terms—IEEE 802.11, protocol capacity, quality of service (QoS), wireless local area networks (WLANs). I.
Citations
|
539
|
Supporting real-time applications in an integrated services packet network: architecture and mechanism
– Clark, Shenker, et al.
- 1992
|
|
428
|
Performance Analysis of the IEEE 802.11 Distributed Coordination Function
– Bianchi
- 2000
|
|
85
|
Queueing Systems Vol I
– Kleinrock
- 1975
|
|
71
|
Performance of Reliable Transport Protocol over
– Wu, Peng, et al.
|
|
67
|
Differentiation Mechanism for
– Aad, Castelluccia
- 2001
|
|
61
|
Distributed Multi-Hop Scheduling and Medium Access with Delay and Throughput Constraints
– Kanodia, Li, et al.
- 2001
|
|
48
|
Supporting Service Differentiation in Wireless Packet Networks Using Distributed Control
– Veres, Campbell, et al.
- 2001
|
|
44
|
IEEE 802.11 protocol: design and performance evaluation of an adaptive backoff mechanism
– Cali’, Conti, et al.
- 2000
|
|
41
|
Voice and Data Transmission over an 802.11 Wireless Network
– Visser, Zarki
- 1995
|
|
32
|
Improving Protocol Capacity with Model-based Frame Scheduling in IEEE 802.11-operated WLANs
– Kim, Hou
- 2003
|
|
31
|
Real-time traffic over the IEEE 802.11 medium access control layer
– Sobrinho, Krishnakumar
- 1996
|
|
23
|
Performance Analysis of the
– Foh, Zukerman
- 2002
|
|
21
|
Performance evaluation of algorithms for wireless medium access
– Bharghavan
- 1998
|
|
21
|
2003. IEEE 802.11e contention-based channel access (EDCF) performance evaluation
– Choi, Prado, et al.
|
|
20
|
A Novel MAC Protocol with Fast Collision Resolution for Wireless LANs
– Kwon, Fang, et al.
- 2003
|
|
19
|
Protection and guarantee for voice and video traffic
– Xiao, Li, et al.
- 2004
|
|
16
|
Support of multimedia service with the
– J-Y, Chen
- 2002
|
|
14
|
A Bandwidth Allocation/Sharing/Extension Protocol for Multimedia Over IEEE 802.11 Ad hoc Wireless LANs
– Sheu, Sheu
- 2001
|
|
13
|
Saturation throughput-delay analysis of
– Hadzi-Velkov, Spasenovski
- 2003
|
|
11
|
One-Way Transmission Time
– 114
- 1999
|
|
10
|
Performance of Wireless LANs Based on
– Zhai, Fang
- 2003
|
|
10
|
Performance analysis of IEEE 802.11 MAC protocols in wireless LANs
– Zhai, Kwon, et al.
- 2004
|
|
6
|
Performance analysis of IEEE 802.11 CSMA/CA medium access control protocol
– Ho, Chen
- 1996
|
|
5
|
Medium access control in mobile ad hoc networks: Challenges and solutions,” Wiley Wireless Commun. Mobile Comput., Special Issue on Ad Hoc Wireless Networks, 2004. to be published. Hongqiang Zhai (S’03) received the B.E. and M.E. degrees in electrical eng
– Zhai, Wang, et al.
- 2004
|
|
2
|
Supplement to Part 11: Medium Access Control Enhancements for Quality of Service
– Draft
- 2004
|
|
1
|
of the IEEE 802.11 protocol to achieve a theoretical throughput limit
– “Tuning
- 2000
|
