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Physics-informed neural networks and functional interpolation for stiff chemical kinetics
Affiliation
Department of Systems & Industrial Engineering, University of ArizonaDepartment of Aerospace & Mechanical Engineering, University of Arizona
Issue Date
2022
Metadata
Show full item recordPublisher
American Institute of Physics Inc.Citation
De Florio, M., Schiassi, E., & Furfaro, R. (2022). Physics-informed neural networks and functional interpolation for stiff chemical kinetics. Chaos, 32(6).Journal
ChaosRights
Copyright © 2022 Author(s).Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
This work presents a recently developed approach based on physics-informed neural networks (PINNs) for the solution of initial value problems (IVPs), focusing on stiff chemical kinetic problems with governing equations of stiff ordinary differential equations (ODEs). The framework developed by the authors combines PINNs with the theory of functional connections and extreme learning machines in the so-called extreme theory of functional connections (X-TFC). While regular PINN methodologies appear to fail in solving stiff systems of ODEs easily, we show how our method, with a single-layer neural network (NN) is efficient and robust to solve such challenging problems without using artifacts to reduce the stiffness of problems. The accuracy of X-TFC is tested against several state-of-the-art methods, showing its performance both in terms of computational time and accuracy. A rigorous upper bound on the generalization error of X-TFC frameworks in learning the solutions of IVPs for ODEs is provided here for the first time. A significant advantage of this framework is its flexibility to adapt to various problems with minimal changes in coding. Also, once the NN is trained, it gives us an analytical representation of the solution at any desired instant in time outside the initial discretization. Learning stiff ODEs opens up possibilities of using X-TFC in applications with large time ranges, such as chemical dynamics in energy conversion, nuclear dynamics systems, life sciences, and environmental engineering. © 2022 Author(s).Note
12 month embargo; published online: 01 June 2022ISSN
1054-1500Version
Final published versionae974a485f413a2113503eed53cd6c53
10.1063/5.0086649