Heterogeneity-aware P2P Wireless Energy Transfer for Balanced Energy Distribution

TL;DR

This paper introduces HetWET, a heterogeneity-aware P2P wireless energy transfer method that dynamically balances energy distribution among devices with varying hardware capabilities, outperforming existing approaches.

Contribution

The paper presents a detailed model of wireless energy transfer considering device heterogeneity and proposes a dynamic peer selection strategy for balanced energy distribution.

Findings

HetWET reduces energy losses compared to existing methods.

HetWET achieves more balanced energy distribution.

Simulation results validate HetWET's effectiveness across heterogeneity scenarios.

Abstract

The recent advances in wireless energy transfer (WET) provide an alternate and reliable option for replenishing the battery of pervasive and portable devices, such as smartphones. The peer-to-peer (P2P) mode of WET brings improved flexibility to the charging process among the devices as they can maintain their mobility while replenishing their battery. Few existing works in P2P-WET unrealistically assume the nodes to be exchanging energy at every opportunity with any other node. Also, energy exchange between the nodes is not bounded by the energy transfer limit in that inter-node meeting duration. In this regard, the parametric heterogeneity (in terms of device's battery capacity and WET hardware) among the nodes also affects the energy transfer bound in each P2P interaction, and thus, may lead to unbalanced network energy distributions. This inherent heterogeneity aspect has not been adequately covered in the P2P-WET literature so far, especially from the point of view of maintaining a balanced energy distribution in the networked population. In this work, we present a Heterogeneity-aware Wireless Energy Transfer (HetWET) method. In contrast to the existing literature, we devise a fine-grained model of wireless energy transfer while considering the parametric heterogeneity of the participating devices. Thereafter, we enable the nodes to explore and dynamically decide the peers for energy exchange. The performance of HetWET is evaluated using extensive simulations with varying heterogeneity settings. The evaluation results demonstrate that HetWET can maintain lower energy losses and achieve more balanced energy variation distance compared to three different state-of-the-art methods.