Resource Allocation in Wireless Powered IoT Networks

TL;DR

This paper proposes a novel resource allocation framework for wireless powered IoT networks, combining user grouping via a matching game and dynamic power control using MDP to enhance throughput efficiently.

Contribution

It introduces an efficient channel allocation algorithm and a distributed power allocation scheme tailored for IoT networks with energy and spectrum constraints.

Findings

ECAA achieves near-optimal performance with low complexity.

Distributed power control outperforms centralized schemes.

The approach effectively manages energy and spectrum resources in IoT networks.

Abstract

In this paper, efficient resource allocation for the uplink transmission of wireless powered IoT networks is investigated. We adopt LoRa technology as an example in the IoT network, but this work is still suitable for other communication technologies. Allocating limited resources, like spectrum and energy resources, among a massive number of users faces critical challenges. We consider grouping wireless powered IoT users into available channels first and then investigate power allocation for users grouped in the same channel to improve the network throughput. Specifically, the user grouping problem is formulated as a many to one matching game. It is achieved by considering IoT users and channels as selfish players which belong to two disjoint sets. Both selfish players focus on maximizing their own utilities. Then we propose an efficient channel allocation algorithm (ECAA) with low complexity for user grouping. Additionally, a Markov Decision Process (MDP) is used to model unpredictable energy arrival and channel conditions uncertainty at each user, and a power allocation algorithm is proposed to maximize the accumulative network throughput over a finite-horizon of time slots. By doing so, we can distribute the channel access and dynamic power allocation local to IoT users. Numerical results demonstrate that our proposed ECAA algorithm achieves near-optimal performance and is superior to random channel assignment, but has much lower computational complexity. Moreover, simulations show that the distributed power allocation policy for each user is obtained with better performance than a centralized offline scheme.