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Bibliographic Details
Main Authors: Åkerstedt, Lucas, Blanco, Darwin, Jonsson, B. L. G.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.18734
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author Åkerstedt, Lucas
Blanco, Darwin
Jonsson, B. L. G.
author_facet Åkerstedt, Lucas
Blanco, Darwin
Jonsson, B. L. G.
contents Frequency domain sweeps of array antennas are well-known to be time-intensive, and different surrogate models have been used to improve the performance. Data-driven model order reduction algorithms, such as the Loewner framework and vector fitting, can be integrated with these adaptive error estimates, in an iterative algorithm, to reduce the number of full-wave simulations required to accurately capture the requested frequency behavior of multiport array antennas. In this work, we propose two novel adaptive methods exploiting a block matrix function which is a key part of the Loewner framework generating system approach. The first algorithm leverages an inherent matrix parameter freedom in the block matrix function to identify frequency points with large errors, whereas the second utilizes the condition number of the block matrix function. Both methods effectively provide frequency domain error estimates, which are essential for improved performance. Numerical experiments on multiport array antenna S-parameters demonstrate the effectiveness of our proposed algorithms within the Loewner framework, where the proposed algorithms reach the smallest errors for the smallest number of frequency points chosen.
format Preprint
id arxiv_https___arxiv_org_abs_2409_18734
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle On Adaptive Frequency Sampling for Data-driven Model Order Reduction Applied to Antenna Responses
Åkerstedt, Lucas
Blanco, Darwin
Jonsson, B. L. G.
Systems and Control
Computational Physics
G.1.1; J.2
Frequency domain sweeps of array antennas are well-known to be time-intensive, and different surrogate models have been used to improve the performance. Data-driven model order reduction algorithms, such as the Loewner framework and vector fitting, can be integrated with these adaptive error estimates, in an iterative algorithm, to reduce the number of full-wave simulations required to accurately capture the requested frequency behavior of multiport array antennas. In this work, we propose two novel adaptive methods exploiting a block matrix function which is a key part of the Loewner framework generating system approach. The first algorithm leverages an inherent matrix parameter freedom in the block matrix function to identify frequency points with large errors, whereas the second utilizes the condition number of the block matrix function. Both methods effectively provide frequency domain error estimates, which are essential for improved performance. Numerical experiments on multiport array antenna S-parameters demonstrate the effectiveness of our proposed algorithms within the Loewner framework, where the proposed algorithms reach the smallest errors for the smallest number of frequency points chosen.
title On Adaptive Frequency Sampling for Data-driven Model Order Reduction Applied to Antenna Responses
topic Systems and Control
Computational Physics
G.1.1; J.2
url https://arxiv.org/abs/2409.18734