Efficiency of particle search methods in smoothed particle hydrodynamics: a comparative study (part I)

IF 0.6 4区工程技术 Q4 MECHANICS

Progress in Computational Fluid Dynamics Pub Date : 2021-01-06 DOI:10.1504/pcfd.2021.10034692

E. Plaza, L. Sigalotti, Luis Pérez, J. Troconis, Wilfredo Angulo, M. Castro

引用次数: 0

Abstract

Nearest neighbour searching is central to the efficiency of smoothed particle hydrodynamics (SPH). Here the performance of the brute force (BF) or direct search (DS), the cell-linked list (CLL), and the KD-tree (KDT) methods in vectorised form are analysed. The results indicate that the efficiency of the SPH calculations is improved with the vectorised cell-linked list (VCLL) and the vectorised KD-tree (VKDT). However, the VKDT approach is more efficient than the VCLL method for N ≤ 105 in two dimensions (2D) and N ≤ 106 in three dimensions (3D). For larger N, the time duration of the SPH calculations with the VKDT method grows steeply while a linear trend is maintained with the VCLL. The complexity here is measured not only for early events but also close to the point of hardware limit, in which the complexity has a different behaviour, which can be measured and compared using a power fit.

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光滑粒子流体力学中粒子搜索方法的效率比较研究(第一部分)

最近邻搜索是光滑粒子流体动力学（SPH）效率的核心。本文分析了矢量化形式的强力（BF）或直接搜索（DS）、单元链表（CLL）和KD树（KDT）方法的性能。结果表明，矢量化小区链表（VCLL）和矢量化KD树（VKDT）提高了SPH计算的效率。然而，对于二维（2D）N≤105和三维（3D）N≤106，VKDT方法比VCLL方法更有效。对于较大的N，使用VKDT方法进行SPH计算的持续时间急剧增长，而使用VCLL保持线性趋势。这里的复杂性不仅是针对早期事件测量的，而且接近硬件极限点，其中复杂性具有不同的行为，可以使用幂拟合来测量和比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Progress in Computational Fluid Dynamics 物理-力学

CiteScore

1.50

自引率

14.30%

发文量

审稿时长

7.5 months

期刊介绍： CFD is now considered an indispensable analysis/design tool in an ever-increasing range of industrial applications. Practical flow problems are often so complex that a high level of ingenuity is required. Thus, besides the development work in CFD, innovative CFD applications are also encouraged. PCFD''s ultimate goal is to provide a common platform for model/software developers and users by balanced international/interdisciplinary contributions, disseminating information relating to development/refinement of mathematical and numerical models, software tools and their innovative applications in CFD. Topics covered include: -Turbulence- Two-phase flows- Heat transfer- Chemical reactions and combustion- Acoustics- Unsteady flows- Free-surfaces- Fluid-solid interaction- Navier-Stokes solution techniques for incompressible and compressible flows- Discretisation methods and schemes- Convergence acceleration procedures- Grid generation and adaptation techniques- Mesh-free methods- Distributed computing- Other relevant topics