QoS-Aware Transmission Policies for OFDM Bidirectional Decode-and-Forward Relaying

TL;DR

This paper proposes a joint optimization framework for OFDM-based bidirectional relay systems that maximizes weighted sum rates while ensuring QoS, using dual methods to solve a complex mixed integer programming problem.

Contribution

It introduces a novel resource allocation scheme that jointly optimizes power, mode selection, and subcarrier assignment for QoS-aware two-way relaying in OFDM systems.

Findings

Significant performance improvement over conventional schemes.

Efficient asymptotically optimal solution via dual method.

Derived capacity region for two-way DF relaying in parallel channels.

Abstract

Two-way relaying can considerably improve spectral efficiency in relay-assisted bidirectional communications. However, the benefits and flexible structure of orthogonal frequency division multiplexing (OFDM)-based two-way decode-and-forward (DF) relay systems is much less exploited. Moreover, most of existing works have not considered quality-of-service (QoS) provisioning for two-way relaying. In this paper, we consider the OFDM-based bidirectional transmission where a pair of users exchange information with or without the assistance of a single DF relay. Each user can communicate with the other via three transmission modes: direct transmission, one-way relaying, and two-way relaying. We jointly optimize the transmission policies, including power allocation, transmission mode selection, and subcarrier assignment for maximizing the weighted sum rates of the two users with diverse quality-of-service (QoS) guarantees. We formulate the joint optimization problem as a mixed integer programming problem. By using the dual method, we efficiently solve the problem in an asymptotically optimal manner. Moreover, we derive the capacity region of two-way DF relaying in parallel channels. Simulation results show that the proposed resource-allocation scheme can substantially improve system performance compared with the conventional schemes. A number of interesting insights are also provided via comprehensive simulations.