Optimality-Preserving Reduction of Chemical Reaction Networks

Kim G. Larsen, Daniele Toller, Mirco Tribastone, Max Tschaikowski, Andrea Vandin*

*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceedingArticle in proceedingsResearchpeer-review

Abstract

Across many disciplines, chemical reaction networks (CRNs) are an established population model defined as a system of coupled nonlinear ordinary differential equations. In many applications, for example, in systems biology and epidemiology, CRN parameters such as the kinetic reaction rates can be used as control inputs to steer the system toward a given target. Unfortunately, the resulting optimal control problem is nonlinear, therefore, computationally very challenging. We address this issue by introducing an optimality-preserving reduction algorithm for CRNs. The algorithm partitions the original state variables into a reduced set of macro-variables for which one can define a reduced optimal control problem with provably identical optimal values. The reduction algorithm runs with polynomial time complexity in the size of the CRN. We use this result to reduce verification and control problems of large-scale vaccination models over real-world networks.
Original languageEnglish
Title of host publicationProceedings of the 12th International Symposium on Leveraging Applications of Formal Methods, Verification and Validation. Rigorous Engineering of Collective Adaptive Systems, ISoLA
Volume15220
PublisherSpringer
Publication date2025
Pages13-32
ISBN (Print)978-3-031-75106-6
ISBN (Electronic)978-3-031-75107-3
DOIs
Publication statusPublished - 2025
Event12th International Symposium on Leveraging Applications of Formal Methods, Verification and Validation (ISoLA 2024) - Crete, Greece
Duration: 27 Oct 202431 Oct 2024

Conference

Conference12th International Symposium on Leveraging Applications of Formal Methods, Verification and Validation (ISoLA 2024)
Country/TerritoryGreece
CityCrete
Period27/10/202431/10/2024

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