Model-free stabilization via Extremum Seeking using a cost neural estimator

Sara Dubbioso; Azarakhsh Jalalvand; Josiah Wai; Gianmaria De Tommasi; Egemen Kolemen

doi:10.1016/j.eswa.2024.125204

Model-free stabilization via Extremum Seeking using a cost neural estimator

Sara Dubbioso, Azarakhsh Jalalvand, Josiah Wai, Gianmaria De Tommasi, Egemen Kolemen

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

In this paper, a fully model-free architecture for vertical stabilization of thermonuclear plasmas in tokamak experimental reactors is presented. For the first time, an Extremum Seeking control algorithm is combined with neural networks to estimate the Lyapunov function to be minimized, resulting in a fully data-driven control architecture. The performance of different neural networks are compared. Specifically, Multilayer Perceptrons and Extreme Learning Machines are considered. The proposed architecture is tested in simulation to show that it can counteract relevant plasma disturbances, resulting in a significant improvement in terms of the achievable operative space compared to the Extremum Seeking algorithm, which still relies on model-based cost estimator.

Original language	English (US)
Article number	125204
Journal	Expert Systems with Applications
Volume	258
DOIs	https://doi.org/10.1016/j.eswa.2024.125204
State	Published - Dec 15 2024

All Science Journal Classification (ASJC) codes

General Engineering
Computer Science Applications
Artificial Intelligence

Keywords

Extremum Seeking
Model-free
Neural network
Plasma vertical stabilization

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10.1016/j.eswa.2024.125204

Cite this

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title = "Model-free stabilization via Extremum Seeking using a cost neural estimator",

abstract = "In this paper, a fully model-free architecture for vertical stabilization of thermonuclear plasmas in tokamak experimental reactors is presented. For the first time, an Extremum Seeking control algorithm is combined with neural networks to estimate the Lyapunov function to be minimized, resulting in a fully data-driven control architecture. The performance of different neural networks are compared. Specifically, Multilayer Perceptrons and Extreme Learning Machines are considered. The proposed architecture is tested in simulation to show that it can counteract relevant plasma disturbances, resulting in a significant improvement in terms of the achievable operative space compared to the Extremum Seeking algorithm, which still relies on model-based cost estimator.",

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T1 - Model-free stabilization via Extremum Seeking using a cost neural estimator

AU - Dubbioso, Sara

AU - Jalalvand, Azarakhsh

AU - Wai, Josiah

AU - De Tommasi, Gianmaria

AU - Kolemen, Egemen

PY - 2024/12/15

Y1 - 2024/12/15

N2 - In this paper, a fully model-free architecture for vertical stabilization of thermonuclear plasmas in tokamak experimental reactors is presented. For the first time, an Extremum Seeking control algorithm is combined with neural networks to estimate the Lyapunov function to be minimized, resulting in a fully data-driven control architecture. The performance of different neural networks are compared. Specifically, Multilayer Perceptrons and Extreme Learning Machines are considered. The proposed architecture is tested in simulation to show that it can counteract relevant plasma disturbances, resulting in a significant improvement in terms of the achievable operative space compared to the Extremum Seeking algorithm, which still relies on model-based cost estimator.

AB - In this paper, a fully model-free architecture for vertical stabilization of thermonuclear plasmas in tokamak experimental reactors is presented. For the first time, an Extremum Seeking control algorithm is combined with neural networks to estimate the Lyapunov function to be minimized, resulting in a fully data-driven control architecture. The performance of different neural networks are compared. Specifically, Multilayer Perceptrons and Extreme Learning Machines are considered. The proposed architecture is tested in simulation to show that it can counteract relevant plasma disturbances, resulting in a significant improvement in terms of the achievable operative space compared to the Extremum Seeking algorithm, which still relies on model-based cost estimator.

KW - Extremum Seeking

KW - Model-free

KW - Neural network

KW - Plasma vertical stabilization

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Model-free stabilization via Extremum Seeking using a cost neural estimator

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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