Joint Spectrum and Power Allocation for Multi-node Cooperative Wireless Systems

TL;DR

This paper proposes a joint spectrum and power allocation scheme for multi-node cooperative wireless systems that minimizes power consumption while satisfying throughput and power constraints, with algorithms verified through simulations.

Contribution

It introduces a new resource allocation scheme and algorithms for cooperative multi-BS systems, optimizing power efficiency and system performance.

Findings

Guaranteed minimum power consumption under certain user conditions.

Effective UE-BS association and complexity reduction schemes.

Simulation results confirm the optimality of the proposed algorithms.

Abstract

Energy efficiency is a growing concern for wireless networks, not only due to the emerging traffic demand from smart devices, but also because of the dependence on the traditional unsustainable energy and the overall environmental concerns. The urgent call for reducing power consumption while meeting system requirements has motivated increasing research efforts on green radio. In this paper, we investigate a new joint spectrum and power allocation scheme for a cooperative downlink multi-user system using the frequency division multiple access scheme, in which arbitrary M base stations (BSs) coordinately allocate their resources to each user equipment (UE). With the assumption that multi-BS UE (user being served by multi-BS) would require the same amount of spectrum from these BSs, we conclude that when the number of multi-BS UEs is limited by M-1, the resource allocation scheme can always guarantee the minimum overall transmit power consumption while meeting the throughput requirement of each UE and also each BS's power constraint. Then, to decide the clusters of multi-BS UEs and the clusters of individual-BS UEs (users being served by individual BSs), we propose a UE-BS association scheme and a complexity reduction scheme. Finally, a novel joint spectrum and power allocation algorithm is proposed to minimize the total power consumption. Simulation results are presented to verify the optimality of the derived schemes.