Delay Analysis for Wireless Local Area Networks with Multipacket Reception under Finite Load

To date, most analysis of WLANs has been focused on their operation under saturation condition. This work is an attempt to understand the fundamental performance of WLANs under unsaturated condition. In particular, we are interested in the delay performance when collisions of packets are resolved by an exponential backoff mechanism. Using a multiple-vacation queueing model, we derive an explicit expression for packet delay distribution. It is found that under some circumstances, mean delay and delay jitter may approach infinity even when the traffic load is way below the saturation throughput. Saturation throughput is therefore not a sound measure of WLAN capacity when the underlying applications are delay sensitive. To bridge the gap, we define safe-bounded-mean-delay (SBMD) throughput and safe-bounded-delay-jitter (SBDJ) throughput that reflect the actual network capacity users can enjoy when they require bounded mean delay and delay jitter, respectively. The analytical model in this paper is general enough to cover both single-packet reception (SPR) and multi-packet reception (MPR) WLANs, as well as carrier-sensing and non-carrier- sensing networks. We show that the SBMD and SBDJ throughputs scale super-linearly with the MPR capability of a network. Together with our earlier work that proves super-linear throughput scaling under saturation condition, our results here complete the demonstration of MPR as a powerful capacity-enhancement technique for both delay-sensitive and delay-tolerant applications.

[1]  A. Girotra,et al.  Performance Analysis of the IEEE 802 . 11 Distributed Coordination Function , 2005 .

[2]  Byung-Jae Kwak,et al.  Performance analysis of exponential backoff , 2005, IEEE/ACM Transactions on Networking.

[3]  Lang Tong,et al.  Stability and delay of finite-user slotted ALOHA with multipacket reception , 2005, IEEE Transactions on Information Theory.

[4]  Yang Xiao,et al.  Performance analysis of priority schemes for IEEE 802.11 and IEEE 802.11e wireless LANs , 2005, IEEE Transactions on Wireless Communications.

[5]  Hongqiang Zhai,et al.  How well can the IEEE 802.11 wireless LAN support quality of service? , 2005, IEEE Transactions on Wireless Communications.

[6]  Ilenia Tinnirello,et al.  Remarks on IEEE 802.11 DCF performance analysis , 2005, IEEE Communications Letters.

[7]  B. T. Doshi,et al.  Queueing systems with vacations — A survey , 1986, Queueing Syst. Theory Appl..

[8]  Hai Le Vu,et al.  MAC Access Delay of IEEE 802.11 DCF , 2007, IEEE Transactions on Wireless Communications.

[9]  Biplab Sikdar,et al.  A queueing model for finite load IEEE 802.11 random access MAC , 2004, 2004 IEEE International Conference on Communications (IEEE Cat. No.04CH37577).

[10]  S. Wittevrongel,et al.  Queueing Systems , 2019, Introduction to Stochastic Processes and Simulation.

[11]  Soung Chang Liew,et al.  How Does Multiple-Packet Reception Capability Scale the Performance of Wireless Local Area Networks? , 2009, IEEE Transactions on Mobile Computing.

[12]  Soung Chang Liew,et al.  Bounded-mean-delay throughput and nonstarvation conditions in Aloha network , 2009, TNET.

[13]  Bernard Fino,et al.  Multiuser detection: , 1999, Ann. des Télécommunications.

[14]  Soung Chang Liew,et al.  Analysis of Exponential Backoff with Multipacket Reception in Wireless Networks , 2006, Proceedings. 2006 31st IEEE Conference on Local Computer Networks.

[15]  Soung Chang Liew,et al.  Bounded-mean-delay throughput and nonstarvation conditions in Aloha network , 2009, TNET.

[16]  Marco Conti,et al.  Dynamic tuning of the IEEE 802.11 protocol to achieve a theoretical throughput limit , 2000, TNET.

[17]  Shivendra S. Panwar,et al.  Throughput and delay analysis for the IEEE 802.11e enhanced distributed channel access , 2006, IEEE Transactions on Communications.

[18]  Soung Chang Liew,et al.  Multipacket Reception in Wireless Local Area Networks , 2006, 2006 IEEE International Conference on Communications.