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Accurate and Efficient Solutions of Densely Discretized Closed Conductors Using a Combined Potential-Field Formulation
Date
2021-01-01
Author
Karaova, Gokhan
Eris, Ozgur
Ergül, Özgür Salih
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We present an accurate, efficient, and stable formulation for rigorous analyses of electromagnetic problems involving closed conductors. The formulation, namely the combined potential-field formulation (CPFF), is constructed from the conventional potential integral equations and the magnetic-field integral equation, together with an additional integral equation using the boundary condition for the normal component of the magnetic vector potential. Being both low-frequency-stable and resonance-free, CPFF is a broadband formulation, which enables accurate and efficient solutions of objects with diverse dimensions and discretization sizes.
Subject Keywords
Broadband solvers
,
surface integral equations
,
potential integral equation
,
low-frequency breakdown
,
internal resonance
,
INTEGRAL-EQUATION
,
ALGORITHM
,
MLFMA
URI
https://hdl.handle.net/11511/94981
DOI
https://doi.org/10.1109/aces53325.2021.00022
Conference Name
International Symposium of the Applied-Computational-Electromagnetics-Society (ACES)
Collections
Department of Electrical and Electronics Engineering, Conference / Seminar
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G. Karaova, O. Eris, and Ö. S. Ergül, “Accurate and Efficient Solutions of Densely Discretized Closed Conductors Using a Combined Potential-Field Formulation,” presented at the International Symposium of the Applied-Computational-Electromagnetics-Society (ACES), ELECTR NETWORK, 2021, Accessed: 00, 2021. [Online]. Available: https://hdl.handle.net/11511/94981.
