A novel queue-length-based CSMA algorithm with improved delay characteristics

Recently, a group of queue-length-based CSMA algorithms have been proposed to achieve throughput optimality in wireless networks with single-hop transmissions. These algorithms suffer from two problems: (1) large delays, and (2) temporal starvation phenomenon, where communication links are inactive for a prolonged period of time before getting service. To mitigate these two problems, in this paper, we propose a novel v(t)-regulated CSMA algorithm which can be implemented in a distributed manner using the RTS/CTS mechanism. Link scheduling is performed such that links with longer queues are favored so as to reduce average delay. The v(t)-regulated CSMA algorithm also ensures a more frequent switch between schedules such that the effect of temporal starvation is reduced. The proposed algorithm is throughput optimal and achieves fully local implementation without global message passing. The thresholds to regulate the proposed algorithm are studied to optimize the upper-bound of the delay performance. We show through both hardware implementation and numerical evaluations that the algorithm indeed mitigates the temporal starvation problem and achieves far better delay performance than one of the other throughput-optimal CSMA algorithms. (c) 2017 Elsevier B.V. All rights reserved.