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An ultraweak space-time variational formulation for the wave equation: Analysis and efficient numerical solution

Julian Henning, Davide Palitta, Valeria Simoncini, Karsten Urban

2022ESAIM. Mathematical modelling and numerical analysis24 citationsDOIOpen Access PDF

Abstract

We introduce an ultraweak space-time variational formulation for the wave equation, prove its well-posedness (even in the case of minimal regularity) and optimal inf-sup stability. Then, we introduce a tensor product-style space-time Petrov–Galerkin discretization with optimal discrete inf-sup stability, obtained by a non-standard definition of the trial space. As a consequence, the numerical approximation error is equal to the residual, which is particularly useful for a posteriori error estimation. For the arising discrete linear systems in space and time, we introduce efficient numerical solvers that appropriately exploit the equation structure, either at the preconditioning level or in the approximation phase by using a tailored Galerkin projection. This Galerkin method shows competitive behavior concerning wall-clock time, accuracy and memory as compared with a standard time-stepping method in particular in low regularity cases. Numerical experiments with a 3D (in space) wave equation illustrate our findings.

Topics & Concepts

DiscretizationMathematicsGalerkin methodMathematical analysisNumerical analysisWave equationTensor (intrinsic definition)Applied mathematicsNumerical stabilitySpace (punctuation)A priori and a posterioriDiscontinuous Galerkin methodStability (learning theory)Tensor productProjection (relational algebra)Finite element methodAlgorithmComputer scienceGeometryPhysicsPhilosophyThermodynamicsMachine learningPure mathematicsEpistemologyOperating systemAdvanced Numerical Methods in Computational MathematicsNumerical methods for differential equationsModel Reduction and Neural Networks