A Deep Reinforcement Learning Framework for Contention-Based Spectrum Sharing
Abstract
The increasing number of wireless devices operating in unlicensed spectrum motivates the development of intelligent adaptive approaches to spectrum access. We consider decentralized contention-based medium access for base stations (BSs) operating on unlicensed shared spectrum, where each BS autonomously decides whether or not to transmit on a given resource. The contention decision attempts to maximize not its own downlink throughput, but rather a network-wide objective. We formulate this problem as a decentralized partially observable Markov decision process with a novel reward structure that provides long term proportional fairness in terms of throughput. We then introduce a two-stage Markov decision process in each time slot that uses information from spectrum sensing and reception quality to make a medium access decision. Finally, we incorporate these features into a distributed reinforcement learning framework for contention-based spectrum access. Our formulation provides decentralized inference, online adaptability and also caters to partial observability of the environment through recurrent Q-learning. Empirically, we find its maximization of the proportional fairness metric to be competitive with a genie-aided adaptive energy detection threshold, while being robust to channel fading and small contention windows.
Cite
@article{arxiv.2110.02736,
title = {A Deep Reinforcement Learning Framework for Contention-Based Spectrum Sharing},
author = {Akash Doshi and Srinivas Yerramalli and Lorenzo Ferrari and Taesang Yoo and Jeffrey G. Andrews},
journal= {arXiv preprint arXiv:2110.02736},
year = {2021}
}
Comments
14 pages, 11 figures, 4 tables