Saved in:
Bibliographic Details
Main Authors: Medeiros, Ruth, de la Rubia, Valentín
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.12785
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912236069453824
author Medeiros, Ruth
de la Rubia, Valentín
author_facet Medeiros, Ruth
de la Rubia, Valentín
contents Time domain simulations are crucial for analyzing transient behavior and broadband responses in electromagnetic problems. However, conventional numerical methods such as finite element method in time domain (FEMTD) and finite difference time domain, can be computationally demanding due to their high-dimensional nature, making large-scale simulations impractical for design optimization and real-time analysis. This paper introduces TA-ROMTD, a time-adaptive reduced order model (ROM) for FEMTD simulations that significantly reduces computational costs while maintaining accuracy. The method alternates between FEMTD and a reduced order model in time domain (ROMTD), using an error estimator to detect when the ROMTD solution loses accuracy and switching back to FEMTD to update the ROM with new data. Thus, TA-ROMTD does not require prior knowledge of the problem, as the ROM is constructed on the fly using FEMTD data. A key feature of this approach is the use of a coarse time step during FEMTD time intervals, capturing essential system dynamics while minimizing computational overhead. By reducing the number of degrees of freedom, this method enables efficient electromagnetic simulations, making it a powerful tool for antenna and microwave circuit design. The efficiency of the TA-ROMTD strategy is demonstrated through numerical examples, including an antipodal Vivaldi antenna, a dielectric resonator antenna, a fully metallic dual-polarization frequency selective surface, and a mushroom-type electromagnetic bandgap structure. These cases show the capability of the proposed approach to achieve accurate solutions while significantly reducing the computation time from tens of hours to minutes.
format Preprint
id arxiv_https___arxiv_org_abs_2502_12785
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle An Adaptive Model Order Reduction Approach for the Finite Element Method in Time Domain in Electromagnetics
Medeiros, Ruth
de la Rubia, Valentín
Computational Physics
Time domain simulations are crucial for analyzing transient behavior and broadband responses in electromagnetic problems. However, conventional numerical methods such as finite element method in time domain (FEMTD) and finite difference time domain, can be computationally demanding due to their high-dimensional nature, making large-scale simulations impractical for design optimization and real-time analysis. This paper introduces TA-ROMTD, a time-adaptive reduced order model (ROM) for FEMTD simulations that significantly reduces computational costs while maintaining accuracy. The method alternates between FEMTD and a reduced order model in time domain (ROMTD), using an error estimator to detect when the ROMTD solution loses accuracy and switching back to FEMTD to update the ROM with new data. Thus, TA-ROMTD does not require prior knowledge of the problem, as the ROM is constructed on the fly using FEMTD data. A key feature of this approach is the use of a coarse time step during FEMTD time intervals, capturing essential system dynamics while minimizing computational overhead. By reducing the number of degrees of freedom, this method enables efficient electromagnetic simulations, making it a powerful tool for antenna and microwave circuit design. The efficiency of the TA-ROMTD strategy is demonstrated through numerical examples, including an antipodal Vivaldi antenna, a dielectric resonator antenna, a fully metallic dual-polarization frequency selective surface, and a mushroom-type electromagnetic bandgap structure. These cases show the capability of the proposed approach to achieve accurate solutions while significantly reducing the computation time from tens of hours to minutes.
title An Adaptive Model Order Reduction Approach for the Finite Element Method in Time Domain in Electromagnetics
topic Computational Physics
url https://arxiv.org/abs/2502.12785