Exploiting the Past to Reduce Delay in CSMA Scheduling: A High-order Markov Chain Approach

TL;DR

This paper introduces a delayed CSMA algorithm that leverages past state information to construct a high-order Markov chain, significantly improving delay performance in multihop wireless networks while maintaining throughput optimality.

Contribution

The paper proposes a novel non-Markovian approach using high-order Markov chains based on past states, enhancing delay performance without extra overhead.

Findings

Achieves throughput optimality with better delay performance.

Reduces delay by up to a factor of 20 in simulations.

Adds virtually no additional overhead to existing CSMA algorithms.

Abstract

Recently several CSMA algorithms based on the Glauber dynamics model have been proposed for multihop wireless scheduling, as viable solutions to achieve the throughput optimality, yet are simple to implement. However, their delay performances still remain unsatisfactory, mainly due to the nature of the underlying Markov chains that imposes a fundamental constraint on how the link state can evolve over time. In this paper, we propose a new approach toward better queueing and delay performance, based on our observation that the algorithm needs not be Markovian, as long as it can be implemented in a distributed manner, achieve the same throughput optimality, while offering far better delay performance for general network topologies. Our approach hinges upon utilizing past state information observed by local link and then constructing a high-order Markov chain for the evolution of the feasible link schedules. We show in theory and simulation that our proposed algorithm, named delayed CSMA, adds virtually no additional overhead onto the existing CSMA-based algorithms, achieves the throughput optimality under the usual choice of link weight as a function of local queue length, and also provides much better delay performance by effectively `de-correlating' the link state process (thus removing link starvation) under any arbitrary network topology. From our extensive simulations we observe that the delay under our algorithm can be often reduced by a factor of 20 over a wide range of scenarios, compared to the standard Glauber-dynamics-based CSMA algorithm.