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Autori principali: Sadjadi, Ebrahim Navid, Garcia, Jesus, Molina, Jose M., Borzabadi, Akbar Hashemi, Abchouyeh, Monireh Asadi
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2501.01994
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author Sadjadi, Ebrahim Navid
Garcia, Jesus
Molina, Jose M.
Borzabadi, Akbar Hashemi
Abchouyeh, Monireh Asadi
author_facet Sadjadi, Ebrahim Navid
Garcia, Jesus
Molina, Jose M.
Borzabadi, Akbar Hashemi
Abchouyeh, Monireh Asadi
contents This paper develops a smooth model identification and self-learning strategy for dynamic systems taking into account possible parameter variations and uncertainties. We have tried to solve the problem such that the model follows the changes and variations in the system on a continuous and smooth surface. Running the model to adaptively gain the optimum values of the parameters on a smooth surface would facilitate further improvements in the application of other derivative based optimization control algorithms such as MPC or robust control algorithms to achieve a combined modeling-control scheme. Compared to the earlier works on the smooth fuzzy modeling structures, we could reach a desired trade-off between the model optimality and the computational load. The proposed method has been evaluated on a test problem as well as the non-linear dynamic of a chemical process.
format Preprint
id arxiv_https___arxiv_org_abs_2501_01994
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fuzzy Model Identification and Self Learning with Smooth Compositions
Sadjadi, Ebrahim Navid
Garcia, Jesus
Molina, Jose M.
Borzabadi, Akbar Hashemi
Abchouyeh, Monireh Asadi
Systems and Control
Artificial Intelligence
This paper develops a smooth model identification and self-learning strategy for dynamic systems taking into account possible parameter variations and uncertainties. We have tried to solve the problem such that the model follows the changes and variations in the system on a continuous and smooth surface. Running the model to adaptively gain the optimum values of the parameters on a smooth surface would facilitate further improvements in the application of other derivative based optimization control algorithms such as MPC or robust control algorithms to achieve a combined modeling-control scheme. Compared to the earlier works on the smooth fuzzy modeling structures, we could reach a desired trade-off between the model optimality and the computational load. The proposed method has been evaluated on a test problem as well as the non-linear dynamic of a chemical process.
title Fuzzy Model Identification and Self Learning with Smooth Compositions
topic Systems and Control
Artificial Intelligence
url https://arxiv.org/abs/2501.01994