Guest Editorial Frontiers in Computational Electromagnetics

被引：0

作者：

Notaros B.M. ^{[1
]}

Andriulli F.P. ^{[2
]}

Bagci H. ^{[3
]}

机构：

[1] Colorado State University, Department of Electrical and Computer Engineering, Fort Collins, 80 523, CO

[2] Politecnico di Torino, Department of Electronics and Telecommunications, Turin

[3] King Abdullah University of Science and Technology, Computer, Electrical, Mathematical Science and Engineering (CEMSE) Division, Thuwal

来源：

IEEE Transactions on Antennas and Propagation | 2023年 / 71卷 / 12期

关键词：

Cost effectiveness - Electromagnetic fields - Numerical methods;

D O I：

10.1109/TAP.2023.3337967

中图分类号：

学科分类号：

摘要：

Computational electromagnetics (CEM) seeks numerical solutions to practical engineering problems involving electromagnetic fields and waves and their interactions with materials and designed structures and systems. While physical measurement of electromagnetic fields is often expensive and impractical, CEM develops cost-effective and efficient simulation tools to analyze, design, and optimize real-world devices, structures, and systems. Advancements in CEM rely on those in mathematical representation of physical problems, numerical foundations of methods and algorithms, and computing hardware and software infrastructure. Indeed, CEM research and practice demand the seamless but also the most advanced combination of advancements in engineering, physics, mathematics, and computer science, holding immense potential for transformative impact. CEM is one of the most challenging areas of computational science and engineering due to the inherent complexity of electromagnetic problems. Unlike problems in other disciplines, electromagnetic problems are truly 3-D, volumetric, and vector-based and involve radiation and interaction at a distance. © 1963-2012 IEEE.

引用

页码：9175 / 9177

页数：2

共 17 条

[1]

Cheng Y., Et al., Towards the development of a three-dimensional SBP-SAT FDTD method: Theory and validation, IEEE Trans. Antennas Propag., 71, 12, pp. 9178-9193

[2]

Wang X., Chen G., Yang S., Li Y., Du W., Su D., An FCC-FDTD method on nonuniform grids with guaranteed stability for electromagnetic analysis, IEEE Trans. Antennas Propag., 71, 12, pp. 9194-9206

[3]

Deng L., Et al., A symmetric FDTD subgridding method with guaranteed stability and arbitrary grid ratio, IEEE Trans. Antennas Propag., 71, 12, pp. 9207-9221

[4]

Wang J., Ren Q., A 3-D hybrid Maxwell’s equations finite-difference time-domain (ME-FDTD)/wave equation finite-element time-domain (WE-FETD) method, IEEE Trans. Antennas Propag., 71, 6, pp. 5212-5220, (2023)

[5]

Li S.P., Shi Y., Zhu S.C., Ban Z.G., A global–local error-driven p-adaptive scheme for discontinuous Galerkin time domain method with local time stepping strategy, IEEE Trans. Antennas Propag., 71, 12, pp. 9222-9232

[6]

Zhou Y., Wang L., Ren Q., Liang B., Liu Q.H., Simulation of electromagnetic waves in magnetized cold plasma by a novel BZT-DGTD method, IEEE Trans. Antennas Propag., 71, 12, pp. 9233-9244

[7]

Cao H., Ren Q., Novel discontinuous Galerkin time-domain method for analyzing scattering from three-dimensional bi-isotropic objects, IEEE Trans. Antennas Propag., 71, 12, pp. 9245-9254

[8]

Sayed S.B., Chen R., Ulku H.A., Bagci H., A time domain volume integral equation solver to analyze electromagnetic scattering from nonlinear dielectric objects, IEEE Trans. Antennas Propag., 71, 12, pp. 9255-9267

[9]

Aktepe A., Ulku H.A., Evaluation of the retarded-time potentials due to an impulsively excited curvilinear RWG function, IEEE Trans. Antennas Propag., 71, 12, pp. 9268-9276

[10]

Hofmann B., Eibert T.F., Andriulli F.P., Adrian S.B., A low-frequency stable, excitation agnostic discretization of the right-hand side for the electric field integral equation on multiply-connected geometries, IEEE Trans. Antennas Propag., 71, 12, pp. 9277-9288

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