On the Discrete-Time Minimum Principle in Multiple-Mode Systems

José Daniel López-Barrientos; Manuel Jiménez-Lizárraga; Beatris Adriana Escobedo-Trujillo

doi:10.1080/01969722.2023.2175492

On the Discrete-Time Minimum Principle in Multiple-Mode Systems

José Daniel López-Barrientos, Manuel Jiménez-Lizárraga, Beatris Adriana Escobedo-Trujillo

Anahuac Mexico Universtiy

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

1 Scopus citations

Abstract

This paper presents a robust version of the discrete-time minimum principle for uncertain systems. The uncertainty enters the dynamics of the system by an unknown value that belongs to a finite set. Each element of such a set represents a possible dynamic realization of the discrete-time trajectory. Following a mathematical programming approach, we reformulate the problem to obtain general necessary conditions that allow finding the worst-case optimality in the form of a weighted sum. These conditions are then applied to the time-varying linear affine quadratic problem with multiple modes and a general cost, which includes tracking signals in both: the state and the control variables. We illustrate our result with an application to a production-inventory control problem with uncertain dynamics.

Original language	English
Journal	Cybernetics and Systems
DOIs	https://doi.org/10.1080/01969722.2023.2175492
State	Accepted/In press - 1 Jan 2023

Keywords

Discrete-time systems
multiple-mode systems
numerical procedure
optimal control

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10.1080/01969722.2023.2175492

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abstract = "This paper presents a robust version of the discrete-time minimum principle for uncertain systems. The uncertainty enters the dynamics of the system by an unknown value that belongs to a finite set. Each element of such a set represents a possible dynamic realization of the discrete-time trajectory. Following a mathematical programming approach, we reformulate the problem to obtain general necessary conditions that allow finding the worst-case optimality in the form of a weighted sum. These conditions are then applied to the time-varying linear affine quadratic problem with multiple modes and a general cost, which includes tracking signals in both: the state and the control variables. We illustrate our result with an application to a production-inventory control problem with uncertain dynamics.",

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AU - Jiménez-Lizárraga, Manuel

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N2 - This paper presents a robust version of the discrete-time minimum principle for uncertain systems. The uncertainty enters the dynamics of the system by an unknown value that belongs to a finite set. Each element of such a set represents a possible dynamic realization of the discrete-time trajectory. Following a mathematical programming approach, we reformulate the problem to obtain general necessary conditions that allow finding the worst-case optimality in the form of a weighted sum. These conditions are then applied to the time-varying linear affine quadratic problem with multiple modes and a general cost, which includes tracking signals in both: the state and the control variables. We illustrate our result with an application to a production-inventory control problem with uncertain dynamics.

AB - This paper presents a robust version of the discrete-time minimum principle for uncertain systems. The uncertainty enters the dynamics of the system by an unknown value that belongs to a finite set. Each element of such a set represents a possible dynamic realization of the discrete-time trajectory. Following a mathematical programming approach, we reformulate the problem to obtain general necessary conditions that allow finding the worst-case optimality in the form of a weighted sum. These conditions are then applied to the time-varying linear affine quadratic problem with multiple modes and a general cost, which includes tracking signals in both: the state and the control variables. We illustrate our result with an application to a production-inventory control problem with uncertain dynamics.

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KW - multiple-mode systems

KW - numerical procedure

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JO - Cybernetics and Systems

JF - Cybernetics and Systems

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On the Discrete-Time Minimum Principle in Multiple-Mode Systems

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