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Main Authors: Liu, Peng, Hua, Meng, Chen, Guangji, Wang, Xinyi, Fei, Zesong
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.07598
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author Liu, Peng
Hua, Meng
Chen, Guangji
Wang, Xinyi
Fei, Zesong
author_facet Liu, Peng
Hua, Meng
Chen, Guangji
Wang, Xinyi
Fei, Zesong
contents In this paper,we investigate a novel wireless powered mobile edge computing (MEC) system assisted by pinching antennas (PAs), where devices first harvest energy from a base station and then offload computation-intensive tasks to an MEC server. As an emerging technology, PAs utilize long dielectric waveguides embedded with multiple localized dielectric particles, which can be spatially configured through a pinching mechanism to effectively reduce large-scale propagation loss. This capability facilitates both efficient downlink energy transfer and uplink task offloading. To fully exploit these advantages, we adopt a non-orthogonal multiple access (NOMA) framework and formulate a joint optimization problem to maximize the system's computational capacity by jointly optimizing device transmit power, time allocation, PA positions in both uplink and downlink, and radiation control. To address the resulting non-convexity caused by variable coupling, we develop an alternating optimization algorithm that integrates particle swarm optimization (PSO) with successive convex approximation. Simulation results demonstrate that the proposed PA-assisted design substantially improves both energy harvesting efficiency and computational performance compared to conventional antenna systems.
format Preprint
id arxiv_https___arxiv_org_abs_2506_07598
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Computation Capacity Maximization for Pinching Antennas-Assisted Wireless Powered MEC Systems
Liu, Peng
Hua, Meng
Chen, Guangji
Wang, Xinyi
Fei, Zesong
Signal Processing
In this paper,we investigate a novel wireless powered mobile edge computing (MEC) system assisted by pinching antennas (PAs), where devices first harvest energy from a base station and then offload computation-intensive tasks to an MEC server. As an emerging technology, PAs utilize long dielectric waveguides embedded with multiple localized dielectric particles, which can be spatially configured through a pinching mechanism to effectively reduce large-scale propagation loss. This capability facilitates both efficient downlink energy transfer and uplink task offloading. To fully exploit these advantages, we adopt a non-orthogonal multiple access (NOMA) framework and formulate a joint optimization problem to maximize the system's computational capacity by jointly optimizing device transmit power, time allocation, PA positions in both uplink and downlink, and radiation control. To address the resulting non-convexity caused by variable coupling, we develop an alternating optimization algorithm that integrates particle swarm optimization (PSO) with successive convex approximation. Simulation results demonstrate that the proposed PA-assisted design substantially improves both energy harvesting efficiency and computational performance compared to conventional antenna systems.
title Computation Capacity Maximization for Pinching Antennas-Assisted Wireless Powered MEC Systems
topic Signal Processing
url https://arxiv.org/abs/2506.07598