Almost Optimal Channel Access in Multi-Hop Networks With Unknown Channel Variables

Abstract

We consider distributed channel access in multi-hop cognitive radio networks. Previous works on opportunistic channel access using multi-armed bandits (MAB) mainly focus on single-hop networks that assume complete conflicts among all secondary users. In the multi-hop multi-channel network settings studied here, there is more general competition among different communication pairs. We formulate the problem as a linearly combinatorial MAB problem that involves a maximum weighted independent set (MWIS) problem with unknown weights which need to learn. Existing methods for MAB where each of N nodes chooses from M channels have exponential time and space complexity O(MN), and poor theoretical guarantee on throughput performance. We propose a distributed channel access algorithm that can achieve 1/ of the optimum averaged throughput where each node has communication complexity O(r2+D) and space complexity O(m) in the learning process, and time complexity O(D m^r) in strategy decision process for an arbitrary wireless network. Here =1+ε is the approximation ratio to MWIS for a local r-hop network with m<N nodes,and D is the number of mini-rounds inside each round of strategy decision. For randomly located networks with an average degree d, the time complexity is O(d^r).