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Auteurs principaux: Kedia, Vatsal, Pinnamaraju, Vivek S., Patil, Dinesh
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2406.03752
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author Kedia, Vatsal
Pinnamaraju, Vivek S.
Patil, Dinesh
author_facet Kedia, Vatsal
Pinnamaraju, Vivek S.
Patil, Dinesh
contents In the context of model-based control of industrial processes, it is a common practice to develop a data-driven linear dynamical model around a specified operating point. However, in applications involving wider operating conditions, representation of the dynamics using a single linear dynamic model is often inadequate, requiring either a nonlinear model or multiple linear models to accommodate the nonlinear behaviour. While the development of the former suffers from the requirements of extensive experiments spanning multiple levels, significant compromise in the nominal product quality and dealing with unmeasured disturbances over wider operating conditions, the latter faces the challenge of model switch scheduling and inadequate description of dynamics for the operating regions in-between. To overcome these challenges, we propose an efficient approach to obtain a parsimonious nonlinear dynamic model by developing multiple linear models from data at multiple operating points, lifting the data features obtained from individual model simulations to adequately accommodate the underlying nonlinear behaviour and finally, sparse optimization techniques to obtain a parsimonious model. The performance and effectiveness of the proposed algorithm is demonstrated through simulation case studies.
format Preprint
id arxiv_https___arxiv_org_abs_2406_03752
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Model fusion for efficient learning of nonlinear dynamical systems
Kedia, Vatsal
Pinnamaraju, Vivek S.
Patil, Dinesh
Systems and Control
In the context of model-based control of industrial processes, it is a common practice to develop a data-driven linear dynamical model around a specified operating point. However, in applications involving wider operating conditions, representation of the dynamics using a single linear dynamic model is often inadequate, requiring either a nonlinear model or multiple linear models to accommodate the nonlinear behaviour. While the development of the former suffers from the requirements of extensive experiments spanning multiple levels, significant compromise in the nominal product quality and dealing with unmeasured disturbances over wider operating conditions, the latter faces the challenge of model switch scheduling and inadequate description of dynamics for the operating regions in-between. To overcome these challenges, we propose an efficient approach to obtain a parsimonious nonlinear dynamic model by developing multiple linear models from data at multiple operating points, lifting the data features obtained from individual model simulations to adequately accommodate the underlying nonlinear behaviour and finally, sparse optimization techniques to obtain a parsimonious model. The performance and effectiveness of the proposed algorithm is demonstrated through simulation case studies.
title Model fusion for efficient learning of nonlinear dynamical systems
topic Systems and Control
url https://arxiv.org/abs/2406.03752