Shared-memory, distributed-memory, and mixed-mode parallelisation of a CFD simulation code

Jackson, Adrian; Campobasso, M. Sergio

doi:10.1007/s00450-011-0162-4

Cited by 9 publications

(8 citation statements)

References 11 publications

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“…integration. It is implemented in Fortran [13] and has been parallelised using MPI [12], with each MPI process working on a set of grid blocks (geometric partitions) of the simulation.…”

Section: Hpcgmentioning

confidence: 99%

Evaluating the Arm Ecosystem for High Performance Computing

Jackson

Turner

Weiland

et al. 2019

Proceedings of the Platform for Advanced Scientific Computing Conference

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In recent years, Arm-based processors have arrived on the HPC scene, offering an alternative the existing status quo, which was largely dominated by x86 processors. In this paper, we evaluate the Arm ecosystem, both the hardware offering and the software stack that is available to users, by benchmarking a production HPC platform that uses Marvell's ThunderX2 processors. We investigate the performance of complex scientific applications across multiple nodes, and we also assess the maturity of the software stack and the ease of use from a users' perspective. This papers finds that the performance across our benchmarking applications is generally as good as, or better, than that of well-established platforms, and we can conclude from our experience that there are no major hurdles that might hinder wider adoption of this ecosystem within the HPC community.

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“…integration. It is implemented in Fortran [13] and has been parallelised using MPI [12], with each MPI process working on a set of grid blocks (geometric partitions) of the simulation.…”

Section: Hpcgmentioning

confidence: 99%

Evaluating the Arm Ecosystem for High Performance Computing

Jackson

Turner

Weiland

et al. 2019

Proceedings of the Platform for Advanced Scientific Computing Conference

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“…Scaling to large numbers of cores requires all parts of an application to be efficiently parallelised, and work to be evenly decomposed across workers. This paper outlines work undertaken [5] to take a parallelised HB CFD application, COSA [6], and enable it to scale efficiently to large numbers of cores. COSA is a finite volume NS code featuring a steady solver, a TD solver for the solution of general unsteady flows [7] [8], and a HB solver for the rapid solution of highly nonlinear unsteady periodic flows [9] [10] [11].…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Load balance and parallel I/O: Optimising COSA for large simulations

2018

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This paper presents the optimisation of the parallel functionalities of the Navier-Stokes Computational Fluid Dynamics research code COSA, a finite volume structured multi-block code featuring a steady solver, a general purpose time-domain solver, and a frequency-domain harmonic balance solver for the rapid solution of unsteady periodic flows. The optimisation focuses on improving the scalability of the parallel input/output functionalities of the code and developing an effective and user-friendly load balancing approach. Both features are paramount for using COSA efficiently for large-scale production simulations using tens of thousands of computational cores. The efficiency enhancements resulting from optimising the parallel I/O functionality and addressing load balance issues has provided up to a 4x performance improvement for unbalanced simulations, and 2x performance improvements for balanced simulations.

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“…The perfect gas equation is used to link internal energy, pressure and density. The The only nonzero entries of the source term S are those of the k and ω equations, given respectively by: COSA is second order accurate in time and space, and uses a very efficient MPI parallelization [18]. The accuracy of the space-and time-discretization has been thoroughly validated by considering a wide set of analytical and experi-220 mental test cases [8,13,17].…”

Section: Navier-stokes Cfd Solver 195mentioning

confidence: 99%

Comparative turbulent three-dimensional Navier–Stokes hydrodynamic analysis and performance assessment of oscillating wings for renewable energy applications

Drofelnik

Campobasso

2016

International Journal of Marine Energy

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Oscillating wings can extract energy from an oncoming water or air stream, and first large-scale marine demonstrators are being tested. Oscillating wing hydrodynamics is highly unsteady, may feature dynamic stall and leading edge vortex shedding, and is significantly three-dimensional due to finite-wing effects.Understanding the interaction of these phenomena is essential for maximizing power generation efficiency. Much of the knowledge on oscillating wing hydrodynamics stemmed from two-dimensional low-Reynolds number computational fluid dynamics studies and laboratory testing; real installations, however, will feature Reynolds numbers higher than 1 million and unavoidable finite-winginduced losses. This study investigates the impact of flow three-dimensionality on the hydrodynamics and the efficiency of a realistic aspect ratio 10 device in a stream with Reynolds number of 1.5 million. The improvements achievable by using endplates to reduce finite-wing-induced losses are also analyzed. Threedimensional time-dependent Navier-Stokes simulations using the shear stress transport turbulence model and a 30-million-cell grid are performed. Detailed comparative hydrodynamic analyses of the finite and the infinite wings reveal that flow three-dimensionality reduces the power generation efficiency of the * Corresponding author finite wing with sharp tips and that with endplates by about 17 % and 12 % respectively. Presented analyses suggest approaches to further reducing these power losses.

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Shared-memory, distributed-memory, and mixed-mode parallelisation of a CFD simulation code

Cited by 9 publications

References 11 publications

Evaluating the Arm Ecosystem for High Performance Computing

Evaluating the Arm Ecosystem for High Performance Computing

Load balance and parallel I/O: Optimising COSA for large simulations

Comparative turbulent three-dimensional Navier–Stokes hydrodynamic analysis and performance assessment of oscillating wings for renewable energy applications

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