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Fully and semi-automated shape differentiation in <b>NGSolve</b>.

Peter Gangl, Kevin Sturm, Michael Neunteufel, Joachim Schöberl

2021PubMed43 citationsDOI

Abstract

In this paper, we present a framework for automated shape differentiation in the finite element software NGSolve. Our approach combines the mathematical Lagrangian approach for differentiating PDE-constrained shape functions with the automated differentiation capabilities of NGSolve. The user can decide which degree of automatisation is required, thus allowing for either a more custom-like or black-box-like behaviour of the software. We discuss the automatic generation of first- and second-order shape derivatives for unconstrained model problems as well as for more realistic problems that are constrained by different types of partial differential equations. We consider linear as well as nonlinear problems and also problems which are posed on surfaces. In numerical experiments, we verify the accuracy of the computed derivatives via a Taylor test. Finally, we present first- and second-order shape optimisation algorithms and illustrate them for several numerical optimisation examples ranging from nonlinear elasticity to Maxwell's equations. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s00158-020-02742-w.

Topics & Concepts

Engineering design processProcess (computing)Computer scienceEngineeringEngineering drawingMechanical engineeringProgramming languageTopology Optimization in EngineeringModel Reduction and Neural NetworksAdvanced Numerical Methods in Computational Mathematics