Florian Lindner scite author profile

For multi-field simulations involving a larger number of different physical fields and in cases where the involved fields or simulation codes change due to new modelling insights, e.g., flexible and robust partitioned coupling schemes are an important prerequisite to keep timeto-solution within reasonable limits. They allow for a fast, almost plug-and-play combination of existing established codes to the respective multi-field simulation environment. In this paper, we study a class of coupling approaches that we originally introduced in order to improve the parallel scalability of partitioned simulations. Due to the symmetric structure of these coupling methods and the use of 'long' vectors of coupling data comprising the input and output of all involved codes at a time, they turn out to be particularly suited also for simulations involving more than two coupled fields. As standard two-field coupling schemes are not suited for such cases as shown in our numerical results, this allows the simulation of a new range of applications in a partitioned way.

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Data transfer in partitioned multi-physics simulations : interpolation & communication

Lindner¹

2019

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ExaFSA: Parallel Fluid-Structure-Acoustic Simulation

Lindner

Totounferoush

Mehl

et al. 2020

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In this paper, we present results of the second phase of the project ExaFSA within the priority program SPP1648-Software for Exascale Computing. Our task was to establish a simulation environment consisting of specialized highly efficient and scalable solvers for the involved physical aspects with a particular focus on the computationally challenging simulation of turbulent flow and propagation of the induced acoustic perturbations. These solvers are then coupled in a modular, robust, numerically efficient and fully parallel way, via the open source coupling library preCICE. Whereas we made a first proof of concept for a three-field simulation (elastic structure, surrounding turbulent acoustic flow in the near-field, and pure acoustic wave propagation in the far-field) in the first phase, we removed several scalability limits in the second phase. In particular, we present new contributions to (a) the initialization of communication between processes of

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Florian Lindner

preCICE – A fully parallel library for multi-physics surface coupling

Partitioned Fluid–Structure–Acoustics Interaction on Distributed Data: Coupling via preCICE

A plug-and-play coupling approach for parallel multi-field simulations

Data transfer in partitioned multi-physics simulations : interpolation & communication

ExaFSA: Parallel Fluid-Structure-Acoustic Simulation

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