Haider M. ALSABBAGH, Jianping CHEN, Youyun XU
Department of Electronic Engineering, Shanghai Jiao Tong University, Shanghai, P.R.China.
DOI: 10.4236/ijcns.2008.11007   PDF    HTML     5,405 Downloads   10,262 Views   Citations

Abstract

In WLANs, stations sharing a common wireless channel are governed by IEEE 802.11 protocol. Many conscious studies have been conducted to utilize this precious medium efficiently. However, most of these studies have been done either under assumption of idealistic channel condition or with unlimited retransmitting number. This paper is devoted to investigate influence of limited retransmissions and error level in the utilizing channel on the network throughput, probability of packet dropping and time to drop a packet. The results show that for networks using basic access mechanism the throughput is suppressed with increasing amount of errors in the transmitting channel over all the range of the retry limit. It is also quite sensitive to the size of the network. On the other side, the networks using four-way handshaking mechanism has a good immunity against the error over the available range of retry limits. Also the throughput is unchangeable with size of the network over the range of retransmission limits. However, the throughput does not change with retry limits when it exceeds the maximum number of the backoff stage in both DCF’s mechanisms. In both mechanisms the probability of dropping a packet is a decreasing function with number of retransmissions and the time to drop a packet in the queue of a station is a strong function to the number of retry limit, size of the network, the utilizing medium access mechanism and amount of errors in the channel.

Keywords

IEEE802.11 DCF, WLAN, MAC Protocol, Throughput, Error-prone Channel.

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Conflicts of Interest

The authors declare no conflicts of interest.

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