Exploiting Channel Correlation and PU Traffic Memory for Opportunistic Spectrum Scheduling

TL;DR

This paper investigates opportunistic spectrum scheduling in cognitive radio networks by exploiting temporal correlations in PU occupancy and channel fading, using a partially observable Markov decision process to optimize performance.

Contribution

It introduces a framework that considers both PU occupancy and channel fading memory, providing insights into their interaction and proposing near-optimal scheduling policies.

Findings

Optimal scheduling closely matches genie-aided performance.

Exploiting temporal correlations improves spectrum utilization.

Simple greedy policy is optimal in some special cases.

Abstract

We consider a cognitive radio network with multiple primary users (PUs) and one secondary user (SU), where a spectrum server is utilized for spectrum sensing and scheduling the SU to transmit over one of the PU channels opportunistically. One practical yet challenging scenario is when \textit{both} the PU occupancy and the channel fading vary over time and exhibit temporal correlations. Little work has been done for exploiting such temporal memory in the channel fading and the PU occupancy simultaneously for opportunistic spectrum scheduling. A main goal of this work is to understand the intricate tradeoffs resulting from the interactions of the two sets of system states - the channel fading and the PU occupancy, by casting the problem as a partially observable Markov decision process. We first show that a simple greedy policy is optimal in some special cases. To build a clear understanding of the tradeoffs, we then introduce a full-observation genie-aided system, where the spectrum server collects channel fading states from all PU channels. The genie-aided system is used to decompose the tradeoffs in the original system into multiple tiers, which are examined progressively. Numerical examples indicate that the optimal scheduler in the original system, with observation on the scheduled channel only, achieves a performance very close to the genie-aided system. Further, as expected, the optimal policy in the original system significantly outperforms randomized scheduling, pointing to the merit of exploiting the temporal correlation structure in both channel fading and PU occupancy.