Combining Spot and Futures Markets: A Hybrid Market Approach to Dynamic Spectrum Access

TL;DR

This paper introduces a hybrid spectrum market combining futures and spot trading for secondary spectrum access, optimizing allocation efficiency through offline policies and online auctions, addressing stochastic network information.

Contribution

It proposes a novel hybrid market model with an offline optimal allocation policy and an online VCG-based auction mechanism, including a scalable heuristic for large markets.

Findings

The offline policy maximizes expected spectrum utilization.

The VCG auction ensures truthful bidding and efficient allocation.

The heuristic mechanism offers a polynomial-time solution with bounded performance loss.

Abstract

Dynamic spectrum access is a new paradigm of secondary spectrum utilization and sharing. It allows unlicensed secondary users (SUs) to exploit opportunistically the under-utilized licensed spectrum. Market mechanism is a widely-used promising means to regulate the consuming behaviours of users and, hence, achieves the efficient allocation and consumption of limited resources. In this paper, we propose and study a hybrid secondary spectrum market consisting of both the futures market and the spot market, in which SUs (buyers) purchase under-utilized licensed spectrum from a spectrum regulator, either through predefined contracts via the futures market, or through spot transactions via the spot market. We focus on the optimal spectrum allocation among SUs in an exogenous hybrid market that maximizes the secondary spectrum utilization efficiency. The problem is challenging due to the stochasticity and asymmetry of network information. To solve this problem, we first derive an off-line optimal allocation policy that maximizes the ex-ante expected spectrum utilization efficiency based on the stochastic distribution of network information. We then propose an on-line VickreyCClarkeCGroves (VCG) auction that determines the real-time allocation and pricing of every spectrum based on the realized network information and the pre-derived off-line policy. We further show that with the spatial frequency reuse, the proposed VCG auction is NP-hard; hence, it is not suitable for on-line implementation, especially in a large-scale market. To this end, we propose a heuristics approach based on an on-line VCG-like mechanism with polynomial-time complexity, and further characterize the corresponding performance loss bound analytically. We finally provide extensive numerical results to evaluate the performance of the proposed solutions.