Energy-Aware Competitive Power Allocation for Heterogeneous Networks Under QoS Constraints

TL;DR

This paper introduces a distributed, energy-efficient power allocation method for uplink HetNets, modeling users as rational agents in a non-cooperative game with a focus on Debreu equilibrium analysis.

Contribution

It characterizes the existence and uniqueness conditions of Debreu equilibria in energy-aware power allocation for HetNets and proposes an iterative distributed algorithm.

Findings

The proposed algorithm converges to equilibrium under certain conditions.

Energy efficiency improves with the proposed power allocation scheme.

Simulation results validate the theoretical analysis and show performance gains.

Abstract

This work proposes a distributed power allocation scheme for maximizing energy efficiency in the uplink of orthogonal frequency-division multiple access (OFDMA)-based heterogeneous networks (HetNets). The user equipment (UEs) in the network are modeled as rational agents that engage in a non-cooperative game where each UE allocates its available transmit power over the set of assigned subcarriers so as to maximize its individual utility (defined as the user's throughput per Watt of transmit power) subject to minimum-rate constraints. In this framework, the relevant solution concept is that of Debreu equilibrium, a generalization of Nash equilibrium which accounts for the case where an agent's set of possible actions depends on the actions of its opponents. Since the problem at hand might not be feasible, Debreu equilibria do not always exist. However, using techniques from fractional programming, we provide a characterization of equilibrial power allocation profiles when they do exist. In particular, Debreu equilibria are found to be the fixed points of a water-filling best response operator whose water level is a function of minimum rate constraints and circuit power. Moreover, we also describe a set of sufficient conditions for the existence and uniqueness of Debreu equilibria exploiting the contraction properties of the best response operator. This analysis provides the necessary tools to derive a power allocation scheme that steers the network to equilibrium in an iterative and distributed manner without the need for any centralized processing. Numerical simulations are then used to validate the analysis and assess the performance of the proposed algorithm as a function of the system parameters.