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Auteurs principaux: Cao, Miao, Liu, Zicheng, Matkerim, Bazargul, Wu, Tongning, Li, Changyou, Zong, Yali, Qi, Bo
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2512.10634
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author Cao, Miao
Liu, Zicheng
Matkerim, Bazargul
Wu, Tongning
Li, Changyou
Zong, Yali
Qi, Bo
author_facet Cao, Miao
Liu, Zicheng
Matkerim, Bazargul
Wu, Tongning
Li, Changyou
Zong, Yali
Qi, Bo
contents Fifth-generation (5G) communication systems, operating in higher frequency bands from 3 to 300 GHz, provide unprecedented bandwidth to enable ultra-high data rates and low-latency services. However, the use of millimeter-wave frequencies raises public health concerns regarding prolonged electromagnetic radiation (EMR) exposure. Above 6 GHz, the incident power density (IPD) is used instead of the specific absorption rate (SAR) for exposure assessment, owing to the shallow penetration depth of millimeter waves. This paper proposes a hybrid field reconstruction framework that integrates classical electromagnetic algorithms with deep learning to evaluate the IPD of wireless communication devices operating at 30 GHz, thereby determining compliance with established RF exposure limits. An initial estimate of the electric field on the evaluation plane is obtained using a classical reconstruction algorithm, followed by refinement through a neural network model that learns the mapping between the initial and accurate values. A multi-antenna dataset, generated via full-wave simulation, is used for training and testing. The impacts of training strategy, initial-value algorithm, reconstruction distance, and measurement sampling density on model performance are analyzed. Results show that the proposed method significantly improves reconstruction accuracy, achieving an average relative error of 4.57% for electric field reconstruction and 2.97% for IPD estimation on the test dataset. Additionally, the effects of practical uncertainty factors, including probe misalignment, inter-probe coupling, and measurement noise, are quantitatively assessed.
format Preprint
id arxiv_https___arxiv_org_abs_2512_10634
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Field Reconstruction for High-Frequency Electromagnetic Exposure Assessment Based on Deep Learning
Cao, Miao
Liu, Zicheng
Matkerim, Bazargul
Wu, Tongning
Li, Changyou
Zong, Yali
Qi, Bo
Applied Physics
Fifth-generation (5G) communication systems, operating in higher frequency bands from 3 to 300 GHz, provide unprecedented bandwidth to enable ultra-high data rates and low-latency services. However, the use of millimeter-wave frequencies raises public health concerns regarding prolonged electromagnetic radiation (EMR) exposure. Above 6 GHz, the incident power density (IPD) is used instead of the specific absorption rate (SAR) for exposure assessment, owing to the shallow penetration depth of millimeter waves. This paper proposes a hybrid field reconstruction framework that integrates classical electromagnetic algorithms with deep learning to evaluate the IPD of wireless communication devices operating at 30 GHz, thereby determining compliance with established RF exposure limits. An initial estimate of the electric field on the evaluation plane is obtained using a classical reconstruction algorithm, followed by refinement through a neural network model that learns the mapping between the initial and accurate values. A multi-antenna dataset, generated via full-wave simulation, is used for training and testing. The impacts of training strategy, initial-value algorithm, reconstruction distance, and measurement sampling density on model performance are analyzed. Results show that the proposed method significantly improves reconstruction accuracy, achieving an average relative error of 4.57% for electric field reconstruction and 2.97% for IPD estimation on the test dataset. Additionally, the effects of practical uncertainty factors, including probe misalignment, inter-probe coupling, and measurement noise, are quantitatively assessed.
title Field Reconstruction for High-Frequency Electromagnetic Exposure Assessment Based on Deep Learning
topic Applied Physics
url https://arxiv.org/abs/2512.10634