Multicomputer networks: message-based parallel processing
Multicomputer networks: message-based parallel processing
Data networks (2nd ed.)
Capacity of Ad Hoc wireless networks
Proceedings of the 7th annual international conference on Mobile computing and networking
Communication Networking: An Analytical Approach
Communication Networking: An Analytical Approach
Performance analysis of IEEE 802.11 MAC protocols in wireless LANs: Research Articles
Wireless Communications & Mobile Computing - Special Issue: Emerging WLAN Apllications and Technologies
Analytical models for single-hop and multi-hop ad hoc networks
Mobile Networks and Applications - Special issue: Recent advances in wireless networking
Throughput analysis and admission control for IEEE 802.11a
Mobile Networks and Applications
IEEE/ACM Transactions on Networking (TON)
Performance analysis of the IEEE 802.11 distributed coordination function
IEEE Journal on Selected Areas in Communications
SRN models for analysis of multihop wireless ad hoc networks
EPEW'12 Proceedings of the 9th European conference on Computer Performance Engineering
SRN models for analysis of multihop wireless ad hoc networks
EPEW'12 Proceedings of the 9th European conference on Computer Performance Engineering
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Several analytical models of different wireless networking schemes such as wireless LANs and meshes have been reported in the literature. To the best of our knowledge, all these models fail to address the accurate end-to-end delay analysis of multi-hop wireless networks under unsaturated traffic condition considering the hidden and exposed terminal situation. In an effort to gain deep understanding of delay, this paper firstly proposes a new analytical model to predict accurate media access delay by obtaining its distribution function in a single wireless node. The interesting point of having the media access delay distribution is its generality that not only enables us to derive the average delay which has been reported in almost most of the previous studies as a special case but also facilitates obtaining higher moments of delay such as variance and skewness to capture the QoS parameters such as jitters in recently popular multimedia applications. Secondly, using the obtained single node media access delay distribution, we extend our modeling approach to investigate the delay in multi-hop networks. Moreover, probabilities of collisions in both hidden and exposed terminal conditions have been calculated. The validity of the model is demonstrated by comparing results predicted by the analytical model against those obtained through simulation experiments.