Litcius/Paper detail

wPINNs: Weak Physics Informed Neural Networks for Approximating Entropy Solutions of Hyperbolic Conservation Laws

Tim De Ryck, Siddhartha Mishra, Roberto Molinaro

2024SIAM Journal on Numerical Analysis43 citationsDOI

Abstract

.Physics informed neural networks (PINNs) require regularity of solutions of the underlying PDE to guarantee accurate approximation. Consequently, they may fail at approximating discontinuous solutions of PDEs such as nonlinear hyperbolic equations. To ameliorate this, we propose a novel variant of PINNs, termed as weak PINNs (wPINNs) for accurate approximation of entropy solutions of scalar conservation laws. wPINNs are based on approximating the solution of a min-max optimization problem for a residual, defined in terms of Kruzkhov entropies, to determine parameters for the neural networks approximating the entropy solution as well as test functions. We prove rigorous bounds on the error incurred by wPINNs and illustrate their performance through numerical experiments to demonstrate that wPINNs can approximate entropy solutions accurately.KeywordsPINNshyperbolic conservation lawsdeep learningMSC codes65M99

Topics & Concepts

Conservation lawMathematicsEntropy (arrow of time)Artificial neural networkApplied mathematicsResidualHyperbolic partial differential equationNonlinear systemScalar (mathematics)Mathematical optimizationMathematical analysisPartial differential equationAlgorithmComputer sciencePhysicsGeometryMachine learningQuantum mechanicsModel Reduction and Neural NetworksFluid Dynamics and Turbulent FlowsProbabilistic and Robust Engineering Design