Passivity-preserving parameterized model order reduction using singular values and matrix interpolation

Elizabeth Rita Samuel; Francesco Ferranti; Luc Knockaert; Tom Dhaene

doi:10.1109/TCPMT.2013.2248196

Passivity-preserving parameterized model order reduction using singular values and matrix interpolation

Elizabeth Rita Samuel, Francesco Ferranti, Luc Knockaert, Tom Dhaene

Applied Physics and Photonics

Research output: Contribution to journal › Article › peer-review

13 Citations (Scopus)

Abstract

We present a parameterized model order reduction method based on singular values and matrix interpolation. First, a fast technique using grammians is utilized to estimate the reduced order, and then common projection matrices are used to build parameterized reduced order models (ROMs). The design space is divided into cells, and a Krylov subspace is computed for each cell vertex model. The truncation of the singular values of the merged Krylov subspaces from the models located at the vertices of each cell yields a common projection matrix per design space cell. Finally, the reduced system matrices are interpolated using positive interpolation schemes to obtain a guaranteed passive parameterized ROM. Pertinent numerical results validate the proposed technique.

Original language	English
Article number	6476648
Pages (from-to)	1028-1037
Number of pages	10
Journal	IEEE Transactions on Components, Packaging and Manufacturing Technology
Volume	3
Issue number	6
DOIs	https://doi.org/10.1109/TCPMT.2013.2248196
Publication status	Published - 13 Mar 2013

Keywords

Grammians
interpolation
parameterized model order reduction (MOR)
passivity
projection matrix
singular values

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10.1109/TCPMT.2013.2248196

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title = "Passivity-preserving parameterized model order reduction using singular values and matrix interpolation",

abstract = "We present a parameterized model order reduction method based on singular values and matrix interpolation. First, a fast technique using grammians is utilized to estimate the reduced order, and then common projection matrices are used to build parameterized reduced order models (ROMs). The design space is divided into cells, and a Krylov subspace is computed for each cell vertex model. The truncation of the singular values of the merged Krylov subspaces from the models located at the vertices of each cell yields a common projection matrix per design space cell. Finally, the reduced system matrices are interpolated using positive interpolation schemes to obtain a guaranteed passive parameterized ROM. Pertinent numerical results validate the proposed technique.",

keywords = "Grammians, interpolation, parameterized model order reduction (MOR), passivity, projection matrix, singular values",

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Passivity-preserving parameterized model order reduction using singular values and matrix interpolation. / Samuel, Elizabeth Rita; Ferranti, Francesco; Knockaert, Luc; Dhaene, Tom.

In: IEEE Transactions on Components, Packaging and Manufacturing Technology, Vol. 3, No. 6, 6476648, 13.03.2013, p. 1028-1037.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Passivity-preserving parameterized model order reduction using singular values and matrix interpolation

AU - Samuel, Elizabeth Rita

AU - Ferranti, Francesco

AU - Knockaert, Luc

AU - Dhaene, Tom

PY - 2013/3/13

Y1 - 2013/3/13

N2 - We present a parameterized model order reduction method based on singular values and matrix interpolation. First, a fast technique using grammians is utilized to estimate the reduced order, and then common projection matrices are used to build parameterized reduced order models (ROMs). The design space is divided into cells, and a Krylov subspace is computed for each cell vertex model. The truncation of the singular values of the merged Krylov subspaces from the models located at the vertices of each cell yields a common projection matrix per design space cell. Finally, the reduced system matrices are interpolated using positive interpolation schemes to obtain a guaranteed passive parameterized ROM. Pertinent numerical results validate the proposed technique.

AB - We present a parameterized model order reduction method based on singular values and matrix interpolation. First, a fast technique using grammians is utilized to estimate the reduced order, and then common projection matrices are used to build parameterized reduced order models (ROMs). The design space is divided into cells, and a Krylov subspace is computed for each cell vertex model. The truncation of the singular values of the merged Krylov subspaces from the models located at the vertices of each cell yields a common projection matrix per design space cell. Finally, the reduced system matrices are interpolated using positive interpolation schemes to obtain a guaranteed passive parameterized ROM. Pertinent numerical results validate the proposed technique.

KW - Grammians

KW - interpolation

KW - parameterized model order reduction (MOR)

KW - passivity

KW - projection matrix

KW - singular values

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Passivity-preserving parameterized model order reduction using singular values and matrix interpolation

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Keywords

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