Is Physical Layer Error Correction Sufficient for Video Multicast over IEEE 802.11g Networks?

Wireless video multicast enables delivery of popular events to many mobile users in a bandwidth efficient manner. However, providing good and stable video quality to a large number of users with varying channel conditions remains elusive. A promising solution to this problem is the use of packet level Forward Error Correction (FEC) mechanisms. However, the adjustment of the FEC rate is not a trivial issue due to the dynamic wireless environment. This decision becomes more complicated if we consider the multi-rate capability of the existing wireless LAN technology that adjusts the transmission rates based on the channel conditions and the coverage range. In this paper, we explore the dynamics of Forward Error Correction (FEC) schemes in multi-rate wireless local area networks. We study the fundamental behavior of a 802.11g network which already has embedded error correction in physical layer, under unicast and broadcast modes in a real outdoor environment. We then explore the effectiveness of packet level FEC over wireless networks with multi-rate capability. In order to evaluate the system quantitatively, we implemented a prototype using open source drivers, and ran experiments. Based on the experimental results, we provide guidelines on how to efficiently use FEC for wireless multicast services in order to improve the overall system performance. We argue that even there is a physical layer error correction, using a higher transmission rate together with stronger FEC is more efficient than using a lower transmission rate with weaker FEC for multicast.

[1]  Thanasis Korakis,et al.  An Experimental Study of Packet Loss and Forward Error Correction in Video Multicast over IEEE 802.11b Network , 2009, 2009 6th IEEE Consumer Communications and Networking Conference.

[2]  Luigi Rizzo,et al.  Effective erasure codes for reliable computer communication protocols , 1997, CCRV.

[3]  Ivan V. Bajic Efficient Error Control for Wireless Video Multicast , 2006, 2006 IEEE Workshop on Multimedia Signal Processing.

[4]  Mingquan Wu,et al.  A Staggered FEC System for Seamless Handoff in Wireless LANs: Implementation Experience and Experimental Study , 2007, Ninth IEEE International Symposium on Multimedia (ISM 2007).

[5]  A. J. McAuley Reliable broadband communication using a burst erasure correcting code , 1990, SIGCOMM 1990.

[6]  Takuro Sato,et al.  Rate Adaptive Reliable Multicast MAC Protocol for WLANs , 2006, 2006 IEEE 63rd Vehicular Technology Conference.

[7]  Peng Ge,et al.  Experimental evaluation of error control for video multicast over wireless LANs , 2001, Proceedings 21st International Conference on Distributed Computing Systems Workshops.

[8]  Pedro Cuenca,et al.  Cross-layer architecture for adaptive video multicast streaming over multirate wireless LANs , 2007, IEEE Journal on Selected Areas in Communications.

[9]  Jenq-Neng Hwang,et al.  Congestion and error control for layered scalable video multicast over WiMAX , 2007, 2007 IEEE Mobile WiMAX Symposium.

[10]  Philip K. McKinley,et al.  An experimental study of adaptive forward error correction for wireless collaborative computing , 2001, Proceedings 2001 Symposium on Applications and the Internet.