A partitioned scheme for adjoint shape sensitivity analysis of fluid-structure interactions involving non-matching meshes

TL;DR

This paper introduces a partitioned adjoint shape sensitivity analysis method for fluid-structure interactions with non-matching meshes, enabling accurate gradient computation while managing computational costs.

Contribution

It presents a novel partitioned approach using auxiliary functions and coupling strategies for adjoint FSI problems with non-matching meshes, avoiding expensive cross-derivatives.

Findings

Complete formulation yields accurate shape gradients.

Reduced gradients are less accurate but computationally cheaper.

Mortar method avoids spurious oscillations at interfaces.

Abstract

This work presents a partitioned solution procedure to compute shape gradients in fluid-structure interaction (FSI) using black-box adjoint solvers. Special attention is paid to project the gradients onto the undeformed configuration. This is due to the mixed Lagrangian-Eulerian formulation of large-displacement FSI in this work. Adjoint FSI problem is partitioned as an assembly of well-known adjoint fluid and structural problems, without requiring expensive cross-derivatives. The sub-adjoint problems are coupled with each other by augmenting the target functions with auxiliary functions, independent of the concrete choice of the underlying adjoint formulations. The auxiliary functions are linear force-based or displacement-based functionals which are readily available in well-established single-disciplinary adjoint solvers. Adjoint structural displacements, adjoint fluid displacements, and domain-based adjoint sensitivities of the fluid are the coupling fields to be exchanged between the adjoint solvers. A reduced formulation is also derived for the case of boundary-based adjoint shape sensitivity analysis for fluids. Numerical studies show that the complete formulation computes accurate shape gradients whereas inaccuracies appear in the reduced gradients, specially in regions of strong flow gradients and near singularities. Nevertheless, reduced gradient formulations are found to be a compromise between computational costs and accuracy. Mapping techniques including nearest element interpolation and the mortar method are studied in computational adjoint FSI. It is numerically shown that the mortar method does not introduce spurious oscillations in primal and sensitivity fields along non-matching interfaces, unlike the nearest element interpolation.