Litcius/Paper detail

PDE-NetGen 1.0: from symbolic partial differential equation (PDE) representations of physical processes to trainable neural network representations

Olivier Pannekoucke, Ronan Fablet

2020Geoscientific model development17 citationsDOIOpen Access PDF

Abstract

Abstract. Bridging physics and deep learning is a topical challenge. While deep learning frameworks open avenues in physical science, the design of physically consistent deep neural network architectures is an open issue. In the spirit of physics-informed neural networks (NNs), the PDE-NetGen package provides new means to automatically translate physical equations, given as partial differential equations (PDEs), into neural network architectures. PDE-NetGen combines symbolic calculus and a neural network generator. The latter exploits NN-based implementations of PDE solvers using Keras. With some knowledge of a problem, PDE-NetGen is a plug-and-play tool to generate physics-informed NN architectures. They provide computationally efficient yet compact representations to address a variety of issues, including, among others, adjoint derivation, model calibration, forecasting and data assimilation as well as uncertainty quantification. As an illustration, the workflow is first presented for the 2D diffusion equation, then applied to the data-driven and physics-informed identification of uncertainty dynamics for the Burgers equation.

Topics & Concepts

Computer scienceArtificial neural networkArtificial intelligenceExploitPartial differential equationWorkflowDeep learningBridging (networking)ImplementationPhysical systemIdentification (biology)Variety (cybernetics)Theoretical computer scienceDeep neural networksBurgers' equationData assimilationMachine learningDifferential equationAlgorithmDifferential (mechanical device)Automatic differentiationUncertainty quantificationPartial derivativeFeature (linguistics)Model Reduction and Neural NetworksMachine Learning in Materials ScienceNumerical methods for differential equations