Physics-informed surrogates for electromagnetic dynamics using Transformers and graph neural networks

IF 1.1 4区计算机科学 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Iet Microwaves Antennas & Propagation Pub Date : 2024-02-15 DOI:10.1049/mia2.12463

O. Noakoasteen, C. Christodoulou, Z. Peng, S. K. Goudos

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Abstract

A novel use case for two data-driven models, namely, a Transformer and a convolutional graph neural network (CGNN) is proposed. The authors propose to use these models for emulating the dynamics of electromagnetic (EM) propagation and scattering. The Transformer translates a past sequence into a future sequence by constructing representations from the past and using it to predict the future, taking all of its own previous predictions as input at each step of prediction. The CGNN updates the current state of attribute vectors of each node by passing it information (messages) from all of its neighbouring nodes. We train these models with FDTD simulations of plane waves propagating and scattering from PEC objects. The authors demonstrate that, within the bounds of computational resources, the Transformer can be utilised as a surrogate for EM dynamics, providing 14× speed-up, while the CGNN can be utilised as a next-frame predictor, providing 9× speed-up. When comparing the accuracy of these two models with the authors’ previously developed Encoder-Recurrent-Decoder (ERD) model, it is observed that the error for both the Transformer and the CGNN remains within the same bound for the ERD model. To the best of the authors’ knowledge, this work is the first to utilise the Transformer as a surrogate for EM dynamics.

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使用变压器和图神经网络的电磁动力学物理信息代用器

本文提出了两个数据驱动模型（即变压器和卷积图神经网络 (CGNN)）的新用例。作者建议使用这些模型模拟电磁（EM）传播和散射的动态。转换器通过构建过去的表征，将过去的序列转换为未来的序列，并用它来预测未来，在预测的每一步都将自己之前的所有预测作为输入。CGNN 通过传递来自所有相邻节点的信息（消息）来更新每个节点属性向量的当前状态。我们通过对从 PEC 物体传播和散射的平面波进行 FDTD 仿真来训练这些模型。作者证明，在计算资源允许的范围内，Transformer 可用作电磁动力学的替代物，速度提高了 14 倍，而 CGNN 可用作下一帧预测器，速度提高了 9 倍。在将这两个模型的准确性与作者之前开发的编码器-逆流-解码器（ERD）模型进行比较时，可以发现变换器和 CGNN 的误差与 ERD 模型的误差保持在同一范围内。据作者所知，这项工作是首次利用变换器作为电磁动力学的替代物。

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 Microwaves Antennas & Propagation 工程技术-电信学

CiteScore

4.30

自引率

5.90%

发文量

109

审稿时长

7 months

期刊介绍： Topics include, but are not limited to: Microwave circuits including RF, microwave and millimetre-wave amplifiers, oscillators, switches, mixers and other components implemented in monolithic, hybrid, multi-chip module and other technologies. Papers on passive components may describe transmission-line and waveguide components, including filters, multiplexers, resonators, ferrite and garnet devices. For applications, papers can describe microwave sub-systems for use in communications, radar, aerospace, instrumentation, industrial and medical applications. Microwave linear and non-linear measurement techniques. Antenna topics including designed and prototyped antennas for operation at all frequencies; multiband antennas, antenna measurement techniques and systems, antenna analysis and design, aperture antenna arrays, adaptive antennas, printed and wire antennas, microstrip, reconfigurable, conformal and integrated antennas. Computational electromagnetics and synthesis of antenna structures including phased arrays and antenna design algorithms. Radiowave propagation at all frequencies and environments. Current Special Issue. Call for papers: Metrology for 5G Technologies - https://digital-library.theiet.org/files/IET_MAP_CFP_M5GT_SI2.pdf