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arxiv: 2409.20528 · v1 · pith:FGIL67TI · submitted 2024-09-30 · eess.SY · cs.LG· cs.SY· math.OC

Formally Verified Physics-Informed Neural Control Lyapunov Functions

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classification eess.SY cs.LGcs.SYmath.OC
keywords functionscontrollyapunovneuralequationapproachescharacterizesformal
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Control Lyapunov functions are a central tool in the design and analysis of stabilizing controllers for nonlinear systems. Constructing such functions, however, remains a significant challenge. In this paper, we investigate physics-informed learning and formal verification of neural network control Lyapunov functions. These neural networks solve a transformed Hamilton-Jacobi-Bellman equation, augmented by data generated using Pontryagin's maximum principle. Similar to how Zubov's equation characterizes the domain of attraction for autonomous systems, this equation characterizes the null-controllability set of a controlled system. This principled learning of neural network control Lyapunov functions outperforms alternative approaches, such as sum-of-squares and rational control Lyapunov functions, as demonstrated by numerical examples. As an intermediate step, we also present results on the formal verification of quadratic control Lyapunov functions, which, aided by satisfiability modulo theories solvers, can perform surprisingly well compared to more sophisticated approaches and efficiently produce global certificates of null-controllability.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. A Physics-Informed Scenario Approach with Data Mitigation for Safety Verification of Nonlinear Systems

    eess.SY 2024-12 unverdicted novelty 5.0

    A physics-informed scenario approach selects data samples close to a physics model to reduce dataset size while constructing guaranteed barrier certificates for infinite-horizon safety of nonlinear systems.