A direct Schur–Fourier decomposition for the efficient solution of high‐order Poisson equations on loosely coupled parallel computers

Trias, F. X.; Sòria, M.; Segarra, Carlos David Pérez; Oliva, A.

doi:10.1002/nla.466

Cited by 20 publications

(28 citation statements)

References 31 publications

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“…In both predictor and corrector substeps, the pressure Poisson equation is solved using a direct Schur decomposition [34,35]. Other variants for the fractional step method applied to low Mach flows consider a velocity projection, which results in a variable coefficient Poisson equation [13,14].…”

Section: Pressure-velocity Coupling -Fractional Step Methodsmentioning

confidence: 99%

Numerical analysis of conservative unstructured discretisations for low Mach flows

Ventosa-Molina

Chiva

Lehmkuhl

et al. 2016

Numerical Methods in Fluids

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Summary Unstructured meshes allow easily representing complex geometries and to refine in regions of interest without adding control volumes in unnecessary regions. However, numerical schemes used on unstructured grids have to be properly defined in order to minimise numerical errors. An assessment of a low Mach algorithm for laminar and turbulent flows on unstructured meshes using collocated and staggered formulations is presented. For staggered formulations using cell‐centred velocity reconstructions, the standard first‐order method is shown to be inaccurate in low Mach flows on unstructured grids. A recently proposed least squares procedure for incompressible flows is extended to the low Mach regime and shown to significantly improve the behaviour of the algorithm. Regarding collocated discretisations, the odd–even pressure decoupling is handled through a kinetic energy conserving flux interpolation scheme. This approach is shown to efficiently handle variable‐density flows. Besides, different face interpolations schemes for unstructured meshes are analysed. A kinetic energy‐preserving scheme is applied to the momentum equations, namely, the symmetry‐preserving scheme. Furthermore, a new approach to define the far‐neighbouring nodes of the quadratic upstream interpolation for convective kinematics scheme is presented and analysed. The method is suitable for both structured and unstructured grids, either uniform or not. The proposed algorithm and the spatial schemes are assessed against a function reconstruction, a differentially heated cavity and a turbulent self‐igniting diffusion flame. It is shown that the proposed algorithm accurately represents unsteady variable‐density flows. Furthermore, the quadratic upstream interpolation for convective kinematics scheme shows close to second‐order behaviour on unstructured meshes, and the symmetry‐preserving is reliably used in all computations. Copyright © 2016 John Wiley & Sons, Ltd.

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Section: Pressure-velocity Coupling -Fractional Step Methodsmentioning

confidence: 99%

Numerical analysis of conservative unstructured discretisations for low Mach flows

Ventosa-Molina

Chiva

Lehmkuhl

et al. 2016

Numerical Methods in Fluids

Self Cite

View full text Add to dashboard Cite

show abstract

“…However, the DSFD algorithm that is very efficient on PC clusters cannot be used for an arbitrarily large number of processors and problem size, mainly due to the RAM memory requirements [1] and the size of communications that grow fast with the number of processors and mesh sizes. These problems limit the DSFD solver scalability especially for high-order numerical schemes making it not applicable for large-scale problems on supercomputers using hundreds (or thousands) of processors.…”

Section: Motivation and Summary Of The Present Workmentioning

confidence: 99%

“…In contrast, when using supercomputers the number of CPUs is far greater and network performance much better (especially in terms of latency). It is important to note that depending on the computer architecture, the number of processors and the scale of the problem being solved, these considerations may become even more important than the arithmetical complexity of the algorithm [1]. Therefore algorithms that work well on supercomputers may not work efficiently on PC clusters due to the poor network performance and vice versa.…”

Section: Introductionmentioning

confidence: 99%

“…Our previous version of the code [1,8,9] was conceived for lowcost PC clusters with poor network performance. In that context, a direct Schur complement based method was a good choice for the parallel solution of this set of 2D problems because systems arising from non-uniform meshes can be solved without increasing the computational costs.…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, since the parallelisation of FFT is not efficient on loosely-coupled parallel computers parallelisation in the periodic direction was discarded. Such parallel Poisson solver, named Direct Schur-Fourier Decomposition (DSFD) algorithm [1,9], has been successfully used to perform DNS simulations [4,5] of turbulent natural convection flows in enclosed cavities.…”

Section: Introductionmentioning

confidence: 99%

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