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Main Authors: Do, Loi, Uchytil, Adam, Hurák, Zdeněk
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.01116
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author Do, Loi
Uchytil, Adam
Hurák, Zdeněk
author_facet Do, Loi
Uchytil, Adam
Hurák, Zdeněk
contents Lifted linear predictor (LLP) is an artificial linear dynamical system designed to predict trajectories of a generally nonlinear dynamical system based on the current state (or measurements) and the input. The main benefit of the LLP is its potential ability to capture the nonlinear system's dynamics with precision superior to other linearization techniques, such as local linearization about the operation point. The idea of lifting is supported by the theory of Koopman Operators. For LLP identification, we focus on the data-driven method based on the extended dynamic mode decomposition (EDMD) algorithm. However, while the EDMD algorithm presents an extremely simple and efficient way to obtain the LLP, it can also yield poor results. In this paper, we present some less intuitive practical guidelines for data-driven identification of the LLPs, aiming at improving usability of LLPs for designing control. We support the guidelines with two motivating examples. The implementation of the examples are shared on a public repository.
format Preprint
id arxiv_https___arxiv_org_abs_2408_01116
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Practical Guidelines for Data-driven Identification of Lifted Linear Predictors for Control
Do, Loi
Uchytil, Adam
Hurák, Zdeněk
Systems and Control
Lifted linear predictor (LLP) is an artificial linear dynamical system designed to predict trajectories of a generally nonlinear dynamical system based on the current state (or measurements) and the input. The main benefit of the LLP is its potential ability to capture the nonlinear system's dynamics with precision superior to other linearization techniques, such as local linearization about the operation point. The idea of lifting is supported by the theory of Koopman Operators. For LLP identification, we focus on the data-driven method based on the extended dynamic mode decomposition (EDMD) algorithm. However, while the EDMD algorithm presents an extremely simple and efficient way to obtain the LLP, it can also yield poor results. In this paper, we present some less intuitive practical guidelines for data-driven identification of the LLPs, aiming at improving usability of LLPs for designing control. We support the guidelines with two motivating examples. The implementation of the examples are shared on a public repository.
title Practical Guidelines for Data-driven Identification of Lifted Linear Predictors for Control
topic Systems and Control
url https://arxiv.org/abs/2408.01116