Movable-Antenna-Enhanced Wireless-Powered Mobile-Edge Computing Systems

In this article, we propose a movable antenna (MA)-enhanced scheme for wireless-powered mobile-edge computing (WP-MEC) system, where the hybrid access point (HAP) equipped with multiple MAs first emits wireless energy to charge wireless devices (WDs), and then receives the offloaded tasks from the W...

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Bibliographic Details
Published inIEEE internet of things journal Vol. 11; no. 21; pp. 35505 - 35518
Main Authors Chen, Pengcheng, Yang, Yuxuan, Lyu, Bin, Yang, Zhen, Jamalipour, Abbas
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.11.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Algorithms
Antennas
Beamforming
Computation offloading
Configuration management
Edge computing
Energy conversion
Energy harvesting
MA positioning configurations
Mobile computing
Movable antennas (MAs)
Optimization
Particle swarm optimization
particle swarm optimization with variable local search (PSO-VLS)
Performance enhancement
Radio frequency
Resource management
Servers
Task analysis
Wireless communication
wireless-powered mobile-edge computing (WP-MEC)
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Summary:In this article, we propose a movable antenna (MA)-enhanced scheme for wireless-powered mobile-edge computing (WP-MEC) system, where the hybrid access point (HAP) equipped with multiple MAs first emits wireless energy to charge wireless devices (WDs), and then receives the offloaded tasks from the WDs for edge computing. The MAs deployed at the HAP enhance the spatial Degrees of Freedom (DoFs) by flexibly adjusting the positions of MAs within an available region, thereby improving the efficiency of both downlink wireless energy transfer (WPT) and uplink task offloading. To balance the performance enhancement against the implementation intricacy, we further propose three types of MA positioning configurations, i.e., dynamic MA positioning, semidynamic MA positioning, and static MA positioning. In addition, the nonlinear power conversion of energy harvesting (EH) circuits at the WDs and the finite computing capability at the edge server are taken into account. Our objective is to maximize the sum computational rate (SCR) by jointly optimizing the time allocation, positions of MAs, energy beamforming matrix, receive combing vectors, and offloading strategies of WDs. To solve the nonconvex problems, efficient alternating optimization (AO) frameworks are proposed. Moreover, we propose a hybrid algorithm of particle swarm optimization with variable local search (PSO-VLS) to solve the subproblem of MA positioning. Numerical results validate the superiority of exploiting MAs over the fixed-position antennas (FPAs) for enhancing the SCR performance of WP-MEC systems.
ISSN:2327-4662
2327-4662
DOI:10.1109/JIOT.2024.3437201