A Deep Learning Based Prediction of Specific Absorption Rate Hot-Spots Induced by Broadband Electromagnetic Devices

IF 1.4 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Iet Science Measurement & Technology Pub Date : 2025-04-11 DOI:10.1049/smt2.70009

Shayan Dodge, Nunzia Fontana, Maria Evelina Mognaschi, Eliana Canicattì, Sami Barmada

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Abstract

The rapid growth of wearable electromagnetic devices has raised concerns about the potential health effects of electromagnetic fields, particularly due to their interaction with biological tissues. The key parameter for assessing these effects is the specific absorption rate (SAR), which serves as the standard for evaluating energy absorption and associated thermal effects on the human body. However, traditional numerical methods for SAR estimation are computationally expensive, limiting their application to real-time scenarios. This study addresses this limitation by using a deep learning approach to predict the positions of SAR hotspots efficiently and accurately. A convolutional neural network model was developed to predict hotspot locations with minimal computational effort, using tissue distribution and operating frequencies. The dataset includes tissue images augmented with physical properties such as density and permittivity, the latter being frequency dependent, to enhance the model precision. The proposed method demonstrates robust performance of data-driven approaches in predicting SAR hotspots in real time, providing a foundation for safer and more effective deployment of electromagnetic devices, including wearable and medical applications. The source code used in this study is openly available at https://github.com/ShayanDodge/DL-SAR-Hotspots.

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基于深度学习的宽带电磁器件比吸收率热点预测

可穿戴电磁设备的快速增长引起了人们对电磁场潜在健康影响的担忧，特别是由于它们与生物组织的相互作用。评估这些效应的关键参数是比吸收率（SAR），它是评估人体吸收能量和相关热效应的标准。然而，传统的SAR估计数值方法计算成本高，限制了它们在实时场景中的应用。本研究通过使用深度学习方法来有效准确地预测SAR热点的位置，从而解决了这一限制。利用组织分布和工作频率，开发了卷积神经网络模型，以最小的计算量预测热点位置。该数据集包括增强了物理特性（如密度和介电常数）的组织图像，后者与频率相关，以提高模型精度。所提出的方法展示了数据驱动方法在实时预测SAR热点方面的强大性能，为更安全、更有效地部署电磁设备（包括可穿戴和医疗应用）奠定了基础。本研究中使用的源代码可以在https://github.com/ShayanDodge/DL-SAR-Hotspots上公开获得。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Iet Science Measurement & Technology 工程技术-工程：电子与电气

CiteScore

4.30

自引率

7.10%

发文量

审稿时长

7.5 months

期刊介绍： IET Science, Measurement & Technology publishes papers in science, engineering and technology underpinning electronic and electrical engineering, nanotechnology and medical instrumentation.The emphasis of the journal is on theory, simulation methodologies and measurement techniques. The major themes of the journal are: - electromagnetism including electromagnetic theory, computational electromagnetics and EMC - properties and applications of dielectric, magnetic, magneto-optic, piezoelectric materials down to the nanometre scale - measurement and instrumentation including sensors, actuators, medical instrumentation, fundamentals of measurement including measurement standards, uncertainty, dissemination and calibration Applications are welcome for illustrative purposes but the novelty and originality should focus on the proposed new methods.