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Efficient GPU parallelization of adaptive mesh refinement technique for high-order compressible solver with immersed boundary

Stefano Zaghi, Francesco Salvadore, A. Di Mascio, G. Rossi

2023Computers & Fluids11 citationsDOIOpen Access PDF

Abstract

A new, highly parallelized, adaptive mesh refinement (AMR) library, equipped with an accurate immersed boundary (IB) method for solving the compressible Navier–Stokes system is presented. The library, named ADAM, is designed to efficiently exploit modern exascale GPU-accelerated supercomputers and it is implemented with a highly modular structure in order to make easy to leverage it for a wide range of CFD applications. The structured Cartesian grids at the basis of (octree) AMR approach allows to implement very high order accurate models retaining a low computational cost and high level of parallelization. The accurate IB method coupled with efficient AMR technique enables the simulation flows with complex (possibly moving and deforming) geometries. The library is applied to the simulation of a strong shock diffraction over a solid sphere and a detailed discussion concerning the physical results and the parallel performance obtained is presented.

Topics & Concepts

OctreeComputer scienceComputational scienceAdaptive mesh refinementSolverParallel computingModular designLeverage (statistics)CUDASupercomputerComputational fluid dynamicsAlgorithmMechanicsPhysicsOperating systemMachine learningProgramming languageComputational Fluid Dynamics and AerodynamicsLattice Boltzmann Simulation StudiesFluid Dynamics Simulations and Interactions
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