Multi-Fidelity Optimization of Microwave Structures Using Response Surface Approximation and Space Mapping

Authors

  • Slawomir Koziel Engineering Optimization and Modeling Center, School of Science and Engineering, Reykjavik University, IS-103 Reykjavik, Iceland

Keywords:

Multi-Fidelity Optimization of Microwave Structures Using Response Surface Approximation and Space Mapping

Abstract

A computationally efficient method for design optimization of CPU-intensive microwave structures is discussed. The presented technique exploits a response surface approximation surrogate model set up using data from the coarse-mesh EMbased model being a relaxed-accuracy representation of the microwave structure in question. The surrogate model is further subjected to the classical space mapping optimization. It is demonstrated that the new technique is able to provide a satisfactory design with a few electromagnetic simulations of the original structure. Because of using functional approximation, no circuit equivalent coarse model is necessary, which makes the presented approach particularly suitable for structures for which the development of the reliable coarse model is problematic (e.g., antennas).

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Published

2022-06-17

How to Cite

[1]
S. . Koziel, “Multi-Fidelity Optimization of Microwave Structures Using Response Surface Approximation and Space Mapping”, ACES Journal, vol. 24, no. 6, pp. 600–608, Jun. 2022.

Issue

2009: Vol 24 Iss 6

Section

General Submission