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Main Authors: Liu, Na, Dai, Chengliang, Wu, Qiuyue, Li, Qiuqi, Cai, Guoxiong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.03131
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author Liu, Na
Dai, Chengliang
Wu, Qiuyue
Li, Qiuqi
Cai, Guoxiong
author_facet Liu, Na
Dai, Chengliang
Wu, Qiuyue
Li, Qiuqi
Cai, Guoxiong
contents Model order reduction (MOR) has long been a mainstream strategy to accelerate large-scale transient circuit simulation. Dynamic Mode Decomposition (DMD) represents a novel data-driven characterization method, extracting dominant dynamical modes directly from time-domain simulation data without requiring explicit system equations. This paper first deduces the DMD algorithm and then proposes high order dynamic mode decomposition (HODMD) incorporating delayed embedding technique, specifically targeting computational efficiency in large-scale circuit simulations. Compared with the DMD method, the HODMD method overcomes the problem that the output signal cannot be reconstructed when the spatial resolution is insufficient. The proposed HODMD algorithm is applicable to general circuits and does not impose any constraints on the topology of the pertinent circuit or type of the components. Three representative numerical test cases are presented to systematically validate both the computational efficiency and accuracy of the proposed HODMD method.
format Preprint
id arxiv_https___arxiv_org_abs_2508_03131
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Model Order Reduction for Large-scale Circuits Using Higher Order Dynamic Mode Decomposition
Liu, Na
Dai, Chengliang
Wu, Qiuyue
Li, Qiuqi
Cai, Guoxiong
Signal Processing
Model order reduction (MOR) has long been a mainstream strategy to accelerate large-scale transient circuit simulation. Dynamic Mode Decomposition (DMD) represents a novel data-driven characterization method, extracting dominant dynamical modes directly from time-domain simulation data without requiring explicit system equations. This paper first deduces the DMD algorithm and then proposes high order dynamic mode decomposition (HODMD) incorporating delayed embedding technique, specifically targeting computational efficiency in large-scale circuit simulations. Compared with the DMD method, the HODMD method overcomes the problem that the output signal cannot be reconstructed when the spatial resolution is insufficient. The proposed HODMD algorithm is applicable to general circuits and does not impose any constraints on the topology of the pertinent circuit or type of the components. Three representative numerical test cases are presented to systematically validate both the computational efficiency and accuracy of the proposed HODMD method.
title Model Order Reduction for Large-scale Circuits Using Higher Order Dynamic Mode Decomposition
topic Signal Processing
url https://arxiv.org/abs/2508.03131