Numerical optimal control for distributed delay differential equations: A simultaneous approach based on linearization of the delayed variables

Tobias K. S. Ritschel

doi:10.23919/ECC65951.2025.11187183

Numerical optimal control for distributed delay differential equations: A simultaneous approach based on linearization of the delayed variables

Tobias K. S. Ritschel

Research output: Chapter in Book/Report/Conference proceeding › Book chapter › Research › peer-review

Abstract

Time delays are ubiquitous in industrial processes, and they must be accounted for when designing control algorithms because they have a significant effect on the process dynamics. Therefore, in this work, we propose a simultaneous approach for numerical optimal control of delay differential equations with distributed time delays. Specifically, we linearize the delayed variables around the current time, and we discretize the resulting implicit differential equations using Euler's implicit method. Furthermore, we transcribe the infinite-dimensional optimal control problem into a finite-dimensional nonlinear program, which we solve using Matlab's fmincon. Finally, we demonstrate the efficacy of the approach using a numerical example involving a molten salt nuclear fission reactor.

Original language	English
Title of host publication	Proceedings of 23^rd European Control Conference
Publisher	IEEE
Publication date	2025
Pages	759-764
ISBN (Print)	979-8-3315-0271-3
DOIs	https://doi.org/10.23919/ECC65951.2025.11187183
Publication status	Published - 2025
Event	2025 23^rd European Control Conference (ECC) - Thessaloniki Concert Hall, Thessaloniki, Greece Duration: 24 Jun 2025 → 27 Jun 2025

Conference

Conference	2025 23^rd European Control Conference (ECC)
Location	Thessaloniki Concert Hall
Country/Territory	Greece
City	Thessaloniki
Period	24/06/2025 → 27/06/2025

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10.23919/ECC65951.2025.11187183

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abstract = "Time delays are ubiquitous in industrial processes, and they must be accounted for when designing control algorithms because they have a significant effect on the process dynamics. Therefore, in this work, we propose a simultaneous approach for numerical optimal control of delay differential equations with distributed time delays. Specifically, we linearize the delayed variables around the current time, and we discretize the resulting implicit differential equations using Euler's implicit method. Furthermore, we transcribe the infinite-dimensional optimal control problem into a finite-dimensional nonlinear program, which we solve using Matlab's fmincon. Finally, we demonstrate the efficacy of the approach using a numerical example involving a molten salt nuclear fission reactor.",

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AB - Time delays are ubiquitous in industrial processes, and they must be accounted for when designing control algorithms because they have a significant effect on the process dynamics. Therefore, in this work, we propose a simultaneous approach for numerical optimal control of delay differential equations with distributed time delays. Specifically, we linearize the delayed variables around the current time, and we discretize the resulting implicit differential equations using Euler's implicit method. Furthermore, we transcribe the infinite-dimensional optimal control problem into a finite-dimensional nonlinear program, which we solve using Matlab's fmincon. Finally, we demonstrate the efficacy of the approach using a numerical example involving a molten salt nuclear fission reactor.

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ER -

Numerical optimal control for distributed delay differential equations: A simultaneous approach based on linearization of the delayed variables

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