A high-order partitioned solver for general multiphysics problems and its applications in optimization
Abstract
A high-order accurate adjoint-based optimization framework is presented for unsteady multiphysics problems. The fully discrete adjoint solver relies on the high-order, linearly stable, partitioned solver introduced in [1], where different subsystems are modeled and discretized separately. The coupled system of semi-discretized ordinary differential equations is taken as a monolithic system and partitioned using an implicit-explicit Runge-Kutta (IMEX-RK) discretization [2]. Quantities of interest (QoI) that take the form of space-time integrals are discretized in a solver-consistent manner. The corresponding adjoint equations are derived to compute exact gradients of QoI, which can be solved in a partitioned manner, i.e. subsystem-by-subsystem and substage-by-substage, thanks to the partitioned primal solver. These quantities of interest and their gradients are then used in the context of gradient-based PDE-constrained optimization. The present optimization framework is applied to two fluid-structure interaction problems: 1D piston problem with a three-field formulation and a 2D energy harvesting problem with a two-field formulation.
Cite
@article{arxiv.1812.11853,
title = {A high-order partitioned solver for general multiphysics problems and its applications in optimization},
author = {Daniel Z. Huang and Per-Olof Persson and Matthew J. Zahr},
journal= {arXiv preprint arXiv:1812.11853},
year = {2019}
}
Comments
20 pages, 8 figures. arXiv admin note: substantial text overlap with arXiv:1803.11372