Towards the efficient calculation of quantity of interest from steady Euler equations II: a CNNs-based automatic implementation

TL;DR

This paper enhances a dual-weighted residual-based adaptive method for Euler equations by integrating CNNs, adaptive tolerance strategies, and parallelization to significantly improve computational efficiency in practical applications.

Contribution

It introduces CNN-based solvers, adaptive tolerance adjustment, and parallel computing techniques to accelerate the existing dual-weighted residual method for Euler equations.

Findings

CNN solver maintains dual consistency and accelerates computations.

Adaptive tolerance strategy improves mesh refinement efficiency.

Parallelization with OpenMP significantly reduces simulation time.

Abstract

In \cite{wang2023towards}, a dual-consistent dual-weighted residual-based $h$-adaptive method has been proposed based on a Newton-GMG framework, towards the accurate calculation of a given quantity of interest from Euler equations. The performance of such a numerical method is satisfactory, i.e., the stable convergence of the quantity of interest can be observed in all numerical experiments. In this paper, we will focus on the efficiency issue to further develop this method, since efficiency is vital for numerical methods in practical applications such as the optimal design of the vehicle shape. Three approaches are studied for addressing the efficiency issue, i.e., i). using convolutional neural networks as a solver for dual equations, ii). designing an automatic adjustment strategy for the tolerance in the $h$-adaptive process to conduct the local refinement and/or coarsening of mesh grids, and iii). introducing OpenMP, a shared memory parallelization technique, to accelerate the module such as the solution reconstruction in the method. The feasibility of each approach and numerical issues are discussed in depth, and significant acceleration from those approaches in simulations can be observed clearly from a number of numerical experiments. In convolutional neural networks, it is worth mentioning that the dual consistency plays an important role to guarantee the efficiency of the whole method and that unstructured meshes are employed in all simulations.