Litcius/Paper detail

Deep-HyROMnet: A Deep Learning-Based Operator Approximation for Hyper-Reduction of Nonlinear Parametrized PDEs

Ludovica Cicci, Stefania Fresca, Andrea Manzoni

2022Journal of Scientific Computing38 citationsDOIOpen Access PDF

Abstract

Abstract To speed-up the solution of parametrized differential problems, reduced order models (ROMs) have been developed over the years, including projection-based ROMs such as the reduced-basis (RB) method, deep learning-based ROMs, as well as surrogate models obtained through machine learning techniques. Thanks to its physics-based structure, ensured by the use of a Galerkin projection of the full order model (FOM) onto a linear low-dimensional subspace, the Galerkin-RB method yields approximations that fulfill the differential problem at hand. However, to make the assembling of the ROM independent of the FOM dimension, intrusive and expensive hyper-reduction techniques, such as the discrete empirical interpolation method (DEIM), are usually required, thus making this strategy less feasible for problems characterized by (high-order polynomial or nonpolynomial) nonlinearities. To overcome this bottleneck, we propose a novel strategy for learning nonlinear ROM operators using deep neural networks (DNNs). The resulting hyper-reduced order model enhanced by DNNs, to which we refer to as Deep-HyROMnet, is then a physics-based model, still relying on the RB method approach, however employing a DNN architecture to approximate reduced residual vectors and Jacobian matrices once a Galerkin projection has been performed. Numerical results dealing with fast simulations in nonlinear structural mechanics show that Deep-HyROMnets are orders of magnitude faster than POD-Galerkin-DEIM ROMs, still ensuring the same level of accuracy.

Topics & Concepts

Galerkin methodMathematicsNonlinear systemJacobian matrix and determinantModel order reductionApplied mathematicsDiscretizationProjection (relational algebra)Reduction (mathematics)Interpolation (computer graphics)Deep learningArtificial neural networkAlgorithmMathematical optimizationComputer scienceArtificial intelligenceMathematical analysisQuantum mechanicsPhysicsGeometryMotion (physics)Model Reduction and Neural NetworksMagnetic Properties and ApplicationsNumerical methods for differential equations