GoRINNs: Godunov-Riemann Informed Neural Networks for Learning Hyperbolic Conservation Laws
This work addresses the challenge of solving inverse problems for hyperbolic PDEs with shocks and discontinuities, offering an explainable and conservative alternative to deep learning methods, though it is incremental as it builds on existing numerical schemes.
The authors tackled the inverse problem for hyperbolic conservation laws by developing GoRINNs, a hybrid scheme combining shallow neural networks with Godunov methods, achieving high accuracy in both smooth and discontinuous regions across four benchmark problems.
We present GoRINNs: numerical analysis-informed (shallow) neural networks for the solution of inverse problems of non-linear systems of conservation laws. GoRINNs is a hybrid/blended machine learning scheme based on high-resolution Godunov schemes for the solution of the Riemann problem in hyperbolic Partial Differential Equations (PDEs). In contrast to other existing machine learning methods that learn the numerical fluxes or just parameters of conservative Finite Volume methods, relying on deep neural networks (that may lead to poor approximations due to the computational complexity involved in their training), GoRINNs learn the closures of the conservation laws per se based on "intelligently" numerical-assisted shallow neural networks. Due to their structure, in particular, GoRINNs provide explainable, conservative schemes, that solve the inverse problem for hyperbolic PDEs, on the basis of approximate Riemann solvers that satisfy the Rankine-Hugoniot condition. The performance of GoRINNs is assessed via four benchmark problems, namely the Burgers', the Shallow Water, the Lighthill-Whitham-Richards and the Payne-Whitham traffic flow models. The solution profiles of these PDEs exhibit shock waves, rarefactions and/or contact discontinuities at finite times. We demonstrate that GoRINNs provide a very high accuracy both in the smooth and discontinuous regions.