Reachability of Koopman Linearized Systems Using Random Fourier Feature Observables and Polynomial Zonotope Refinement-Reference-Cited by-同舟云学术

Reachability of Koopman Linearized Systems Using Random Fourier Feature Observables and Polynomial Zonotope Refinement

Published:2022 Issue: Volume: Page:490-510
ISSN:0302-9743
Container-title:Computer Aided Verification
language:
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Author:

Bak Stanley^ORCID,Bogomolov Sergiy^ORCID,Hencey Brandon^ORCID,Kochdumper Niklas^ORCID,Lew Ethan,Potomkin Kostiantyn^ORCID

Abstract

AbstractKoopman operator linearization approximates nonlinear systems of differential equations with higher-dimensional linear systems. For formal verification using reachability analysis, this is an attractive conversion, as highly scalable methods exist to compute reachable sets for linear systems. However, two main challenges are present with this approach, both of which are addressed in this work. First, the approximation must be sufficiently accurate for the result to be meaningful, which is controlled by the choice of observable functions during Koopman operator linearization. By using random Fourier features as observable functions, the process becomes more systematic than earlier work, while providing a higher-accuracy approximation. Second, although the higher-dimensional system is linear, simple convex initial sets in the original space can become complex non-convex initial sets in the linear system. We overcome this using a combination of Taylor model arithmetic and polynomial zonotope refinement. Compared with prior work, the result is more efficient, more systematic and more accurate.

Publisher

Springer International Publishing

Link

https://link.springer.com/content/pdf/10.1007/978-3-031-13185-1_24

Reference43 articles.

1. Althoff, M.: Reachability analysis of nonlinear systems using conservative polynomialization and non-convex sets. In: Proceedings of the International Conference on Hybrid Systems: Computation and Control, pp. 173–182 (2013)

2. Althoff, M.: Reachability analysis of large linear systems with uncertain inputs in the Krylov subspace. Trans. Autom. Control 65(2), 477–492 (2019)

3. Amini, A., et al.: Error bounds for Carleman linearization of general nonlinear systems. In: Proceedings of the International Conference on Control and its Applications, pp. 1–8 (2021)

4. Bak, S., et al.: Numerical verification of affine systems with up to a billion dimensions. In: Proceedings of the International Conference on Hybrid Systems: Computation and Control, pp. 23–32 (2019)

5. Bak, S., et al.: Reachability of black-box nonlinear systems after Koopman operator linearization. In: Proceedings of the International Conference on Analysis and Design of Hybrid Systems, pp. 253–258 (2021)

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