Queueing models for the performance of multihop routing in a intermittently-connected mobile network

Consider an intermittently-connected mobile ad-hoc network with a single source/destination aided by n mobile relay nodes each of which has a finite storage buffer. In this paper we develop, for the first time, an analysis of the steady-state performance of multihop routing in such a network with a general mobility model and characterize it in terms of throughput and transmission-cost overhead. We investigate whether multihop routing has any potential for improvement over two hop routing. We show that analytical models for performance under multihop can be obtained by employing queuing-theoretic techniques and embedded-Markov-chain identification. The solution offered is in the form of non-linear steady-state equations which can be efficiently solved iteratively. The key outcome of this work is that multihop can indeed improve upon two-hop routing in the finite-buffer regime, by means of mitigating the reduction in throughput caused by limited storage (leading to blocking/saturation of buffers). However, the improvement in throughput diminishes as the buffer size grows, and comes at the cost of additional relay-to-relay transmissions.

[1]  Mostafa Ammar,et al.  Routing in Space and Time in Networks with Predictable Mobility , 2004 .

[2]  K. Psounis,et al.  Efficient Routing in Intermittently Connected Mobile Networks: The Single-Copy Case , 2008, IEEE/ACM Transactions on Networking.

[3]  Mostafa H. Ammar,et al.  Message ferrying: proactive routing in highly-partitioned wireless ad hoc networks , 2003, The Ninth IEEE Workshop on Future Trends of Distributed Computing Systems, 2003. FTDCS 2003. Proceedings..

[4]  Faramarz Fekri,et al.  A generalized framework for throughput analysis in sparse mobile networks , 2009, 2009 7th International Symposium on Modeling and Optimization in Mobile, Ad Hoc, and Wireless Networks.

[5]  Ger Koole,et al.  The message delay in mobile ad hoc networks , 2005, Perform. Evaluation.

[6]  Faramarz Fekri,et al.  Analysis of multiple-unicast throughput in finite-buffer Delay-Tolerant Networks , 2009, 2009 IEEE International Symposium on Information Theory.

[7]  R. Subramanian,et al.  Unicast throughput analysis of finite-buffer sparse mobile networks using Markov chains , 2008, 2008 46th Annual Allerton Conference on Communication, Control, and Computing.

[8]  Ahmad Al Hanbali,et al.  Simple Models for the Performance Evaluation of a Class of Two-Hop Relay Protocols , 2007, Networking.

[9]  Mostafa Ammar,et al.  Reliable and efficient message delivery in delay tolerant networks using rateless codes , 2007, MobiOpp '07.

[10]  Lixin Gao,et al.  Estimation based erasure-coding routing in delay tolerant networks , 2006, IWCMC '06.