Learning-based MPC of sampled-data systems with partially unknown dynamics

Seungyong Han; Xuyang Guo; Suneel Kumar Kommuri

doi:10.1016/j.isatra.2025.04.028

Learning-based MPC of sampled-data systems with partially unknown dynamics

Seungyong Han, Xuyang Guo, Suneel Kumar Kommuri^*

^*Corresponding author for this work

Department of Electrical and Electronic Engineering

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

Abstract

In this paper, a novel learning-based model predictive control (LMPC) method is proposed for sampled-data control systems with partially unknown dynamics. Many real-world processes are subject to time-varying parameters and irregular data sampling, making accurate modeling and stability guarantees extremely challenging. To address this, the proposed method uses a neural ordinary differential equation (NODE) to learn unknown time-varying parameter dynamics from irregularly observed data. This learned model is then integrated into the sampled-data MPC framework. In particular, the LMPC method guarantees the system's ultimate boundedness by deriving conditions based on the Gronwall–Bellman inequality. Finally, two practical examples illustrate the applicability of the LMPC method to real-world systems and demonstrate its quantitative stability analysis.

Original language	English
Journal	ISA Transactions
DOIs	https://doi.org/10.1016/j.isatra.2025.04.028
Publication status	Accepted/In press - 2025

Keywords

Learning-based model predictive control
Neural ordinary differential equations
Sampled-data control systems
Ultimate boundedness

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10.1016/j.isatra.2025.04.028

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title = "Learning-based MPC of sampled-data systems with partially unknown dynamics",

abstract = "In this paper, a novel learning-based model predictive control (LMPC) method is proposed for sampled-data control systems with partially unknown dynamics. Many real-world processes are subject to time-varying parameters and irregular data sampling, making accurate modeling and stability guarantees extremely challenging. To address this, the proposed method uses a neural ordinary differential equation (NODE) to learn unknown time-varying parameter dynamics from irregularly observed data. This learned model is then integrated into the sampled-data MPC framework. In particular, the LMPC method guarantees the system's ultimate boundedness by deriving conditions based on the Gronwall–Bellman inequality. Finally, two practical examples illustrate the applicability of the LMPC method to real-world systems and demonstrate its quantitative stability analysis.",

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AU - Han, Seungyong

AU - Guo, Xuyang

AU - Kommuri, Suneel Kumar

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Y1 - 2025

N2 - In this paper, a novel learning-based model predictive control (LMPC) method is proposed for sampled-data control systems with partially unknown dynamics. Many real-world processes are subject to time-varying parameters and irregular data sampling, making accurate modeling and stability guarantees extremely challenging. To address this, the proposed method uses a neural ordinary differential equation (NODE) to learn unknown time-varying parameter dynamics from irregularly observed data. This learned model is then integrated into the sampled-data MPC framework. In particular, the LMPC method guarantees the system's ultimate boundedness by deriving conditions based on the Gronwall–Bellman inequality. Finally, two practical examples illustrate the applicability of the LMPC method to real-world systems and demonstrate its quantitative stability analysis.

AB - In this paper, a novel learning-based model predictive control (LMPC) method is proposed for sampled-data control systems with partially unknown dynamics. Many real-world processes are subject to time-varying parameters and irregular data sampling, making accurate modeling and stability guarantees extremely challenging. To address this, the proposed method uses a neural ordinary differential equation (NODE) to learn unknown time-varying parameter dynamics from irregularly observed data. This learned model is then integrated into the sampled-data MPC framework. In particular, the LMPC method guarantees the system's ultimate boundedness by deriving conditions based on the Gronwall–Bellman inequality. Finally, two practical examples illustrate the applicability of the LMPC method to real-world systems and demonstrate its quantitative stability analysis.

KW - Learning-based model predictive control

KW - Neural ordinary differential equations

KW - Sampled-data control systems

KW - Ultimate boundedness

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M3 - Article

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SN - 0019-0578

JO - ISA Transactions

JF - ISA Transactions

ER -

Learning-based MPC of sampled-data systems with partially unknown dynamics

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Keywords

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