gama-TBSC: Time-Bound Signaling Control with gama-Percent Soft Guarantee in IEEE 802.11 Wireless LANs

Signaling control schemes for wireless multimedia services are expected to maximize the number of newly-accepted mobile terminals (MTs), i.e., system throughput, while maintaining the quality of service (QoS) requirements for the existing MTs in the system. In this paper, we propose a γ-percent time-bound signaling control (γ-TBSC) scheme that resolves a maximum number of MTs mostly within a given bounded time, subject to assuring γ-percent soft guarantee for existing MTs. The γ-TBSC scheme performs signaling control in two phases: the call-invitation phase, and the contention-resolution phase. In the first phase, an access point invites a number of so-called potential MTs to make reservations during a call invitation interval (CII). If any collision occurs, γ-TBSC performs contention resolution in the second phase until all potential MTs are resolved successfully. Most importantly, prior to the two-phase operation, γ-TBSC analytically and statistically determines the potential MT number and the CII length such that the system throughput is maximized and the QoS is soft guaranteed. From simulation results that pit γ-TBSC against several variants of carrier sense multiple access with collision avoidance (CSMA/CA) schemes, we delineate that γ-TBSC outperforms these schemes with respect to throughput and delay performance.

[1]  Sunghyun Choi,et al.  EBA: an enhancement of the IEEE 802.11 DCF via distributed reservation , 2005, IEEE Transactions on Mobile Computing.

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

[3]  Qiang Ni,et al.  Performance analysis and enhancements for IEEE 802.11e wireless networks , 2005, IEEE Network.

[4]  Young-Jong Cho,et al.  Performance Evaluation of IEEE 802.11 Distributed Coordination Function with Virtual Group , 2005, IEICE Trans. Commun..

[5]  Maria C. Yuang,et al.  Multiple access control with intelligent bandwidth allocation for wireless ATM networks , 2000, IEEE Journal on Selected Areas in Communications.

[6]  Maria C. Yuang,et al.  Hexanary-feedback contention access with PDF-based multiuser estimation for wireless access networks , 2004, IEEE Transactions on Wireless Communications.

[7]  A. M. Abdullah,et al.  Wireless lan medium access control (mac) and physical layer (phy) specifications , 1997 .

[8]  Anthony Rowe,et al.  Voice over Sensor Networks , 2006, 2006 27th IEEE International Real-Time Systems Symposium (RTSS'06).

[9]  Hongyi Wu,et al.  An Efficient and Scalable Prioritized MAC Protocol (PMAC) for Backbone Communication in Wireless Sensor Networks , 2009, 2009 Third International Conference on Sensor Technologies and Applications.

[10]  Yuanyuan Yang,et al.  A novel contention-based MAC protocol with channel reservation for wireless LANs , 2008, IEEE Transactions on Wireless Communications.

[11]  Gennaro Boggia,et al.  Feedback-Based Control for Providing Real-Time Services With the 802.11e MAC , 2007, IEEE/ACM Transactions on Networking.

[12]  Yuguang Fang,et al.  Design of MAC protocols with fast collision resolution for wireless local area networks , 2004, IEEE Transactions on Wireless Communications.

[13]  Bo Li,et al.  A new collision resolution mechanism to enhance the performance of IEEE 802.11 DCF , 2004, IEEE Trans. Veh. Technol..

[14]  Ilenia Tinnirello,et al.  Kalman filter estimation of the number of competing terminals in an IEEE 802.11 network , 2003, IEEE INFOCOM 2003. Twenty-second Annual Joint Conference of the IEEE Computer and Communications Societies (IEEE Cat. No.03CH37428).