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Physics-informed neural network Lyapunov functions: PDE characterization, learning, and verification

Jun Liu, Yiming Meng, Maxwell Fitzsimmons, Ruikun Zhou

2025Automatica17 citationsDOIOpen Access PDF

Abstract

We provide a systematic investigation of using physics-informed neural networks to compute Lyapunov functions. We encode Lyapunov conditions as a partial differential equation (PDE) and use this for training neural network Lyapunov functions. We analyze the analytical properties of the solutions to the Lyapunov and Zubov PDEs. In particular, we show that employing the Zubov equation in training neural Lyapunov functions can lead to verifiable approximate regions of attraction close to the true domain of attraction. We also examine approximation errors and the convergence of neural approximations to the unique solution of Zubov’s equation. We then provide sufficient conditions for the learned neural Lyapunov functions that can be readily verified by satisfiability modulo theories (SMT) solvers, enabling formal verification of both local stability analysis and region-of-attraction estimates in the large. Through a number of nonlinear examples, ranging from low to high dimensions, we demonstrate that the proposed framework can outperform traditional sum-of-squares (SOS) Lyapunov functions obtained using semidefinite programming (SDP).

Topics & Concepts

Lyapunov functionArtificial neural networkCharacterization (materials science)Applied mathematicsPhysicsComputer scienceArtificial intelligenceMathematicsQuantum mechanicsOpticsNonlinear systemModel Reduction and Neural NetworksNeural Networks and ApplicationsFault Detection and Control Systems