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Main Authors: Mao, Xin, Chen, Can
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.19165
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author Mao, Xin
Chen, Can
author_facet Mao, Xin
Chen, Can
contents Model reduction plays a critical role in system control, with established methods such as balanced truncation widely used for linear systems. However, extending these methods to nonlinear settings, particularly polynomial dynamical systems that are often used to model higher-order interactions in physics, biology, and ecology, remains a significant challenge. In this article, we develop a novel model reduction method for homogeneous polynomial dynamical systems (HPDSs) with linear input and output grounded in tensor decomposition. Leveraging the inherent tensor structure of HPDSs, we construct reduced models by extracting dominant mode subspaces via higher-order singular value decomposition. Notably, we establish that key system-theoretic properties, including stability, controllability, and observability, are preserved in the reduced model. We demonstrate the effectiveness of our method using numerical examples.
format Preprint
id arxiv_https___arxiv_org_abs_2506_19165
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Model Reduction of Homogeneous Polynomial Dynamical Systems via Tensor Decomposition
Mao, Xin
Chen, Can
Dynamical Systems
Systems and Control
15A72, 93B05, 93B07, 93B11, 93D20
Model reduction plays a critical role in system control, with established methods such as balanced truncation widely used for linear systems. However, extending these methods to nonlinear settings, particularly polynomial dynamical systems that are often used to model higher-order interactions in physics, biology, and ecology, remains a significant challenge. In this article, we develop a novel model reduction method for homogeneous polynomial dynamical systems (HPDSs) with linear input and output grounded in tensor decomposition. Leveraging the inherent tensor structure of HPDSs, we construct reduced models by extracting dominant mode subspaces via higher-order singular value decomposition. Notably, we establish that key system-theoretic properties, including stability, controllability, and observability, are preserved in the reduced model. We demonstrate the effectiveness of our method using numerical examples.
title Model Reduction of Homogeneous Polynomial Dynamical Systems via Tensor Decomposition
topic Dynamical Systems
Systems and Control
15A72, 93B05, 93B07, 93B11, 93D20
url https://arxiv.org/abs/2506.19165