Throughput Optimal Flow Allocation on Multiple Paths for Random Access Wireless Multi-hop Networks
Abstract
In this paper we consider random access wireless multi-hop mesh networks with multi-packet reception capabilities where multiple flows are forwarded to the gateways through node disjoint paths. We address the issue of aggregate throughput-optimal flow rate allocation with bounded delay guarantees. We propose a distributed flow rate allocation scheme that formulates flow rate allocation as an optimization problem and derive the conditions for non-convexity for an illustrative topology. We also employ a simple model for the average aggregate throughput achieved by all flows that captures both intra- and inter-path interference. The proposed scheme is evaluated through NS-2 simulations. Our preliminary results are derived from a grid topology and show that the proposed flow allocation scheme slightly underestimates the average aggregate throughput observed in two simulated scenarios with two and three flows respectively. Moreover it achieves significantly higher average aggregate throughput than single path utilization in two different traffic scenarios examined.
Cite
@article{arxiv.1309.0364,
title = {Throughput Optimal Flow Allocation on Multiple Paths for Random Access Wireless Multi-hop Networks},
author = {Manolis Ploumidis and Nikolaos Pappas and Apostolos Traganitis},
journal= {arXiv preprint arXiv:1309.0364},
year = {2016}
}
Comments
Accepted for publication at the 9th IEEE BROADBAND WIRELESS ACCESS WORKSHOP (BWA2013), IEEE Globecom 2013 Workshops