在平滑拉格朗日粒子轨迹时,二阶多项式核优于高斯核

IF 2.3 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Tim Berk
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引用次数: 0

摘要

粒子加速度的精确重建需要对拉格朗日粒子轨迹进行后处理,以限制微分噪声的放大。在过去二十年中,许多研究都使用了基于截断高斯核的卷积滤波器。本研究评估了以不同标准偏差截断的高斯核的性能。结果表明,与拉格朗日粒子跟踪通常使用的截断相比,更强的截断具有相似的频率响应,但在整体降噪方面更胜一筹。对于等宽的核,使用更强截断的核计算的粒子加速度的噪声最多可降低 20%。另外,与常用截断的高斯内核相比,为了减少噪音,通常可以使用更短的内核,从而减少轨迹端点的数据丢失。研究表明,在最佳截断条件下,高斯核在数学上可以用二阶多项式来近似。在这一限制下,使用多项式核与高斯核相比,结果相同,但计算量减少。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A second-order polynomial kernel outperforms Gaussian kernels when smoothing Lagrangian particle trajectories

A second-order polynomial kernel outperforms Gaussian kernels when smoothing Lagrangian particle trajectories

Accurate reconstruction of particle acceleration requires post-processing of Lagrangian particle trajectories to limit noise amplification by differentiation. Over the past two decades, many studies have used a convolution filter based on a truncated Gaussian kernel. The present work evaluates the performance of Gaussian kernels truncated at varying standard deviations. It is shown that, compared to the truncation typically used in Lagrangian particle tracking, a stronger truncation has a similar frequency response, but is superior in terms of overall noise reduction. For kernels of equal width, particle accelerations calculated using a kernel with stronger truncation have up to 20% lower noise. Alternatively, for a specified reduction in noise a shorter kernel can often be used compared to a Gaussian kernel at the commonly used truncation, resulting in less loss of data at trajectory endpoints. It is shown that at the optimal truncation, a Gaussian kernel is mathematically approximated by a second-order polynomial. In this limit, the use of a polynomial kernel has equal results at reduced computational expense compared to the Gaussian kernel.

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来源期刊
Experiments in Fluids
Experiments in Fluids 工程技术-工程:机械
CiteScore
5.10
自引率
12.50%
发文量
157
审稿时长
3.8 months
期刊介绍: Experiments in Fluids examines the advancement, extension, and improvement of new techniques of flow measurement. The journal also publishes contributions that employ existing experimental techniques to gain an understanding of the underlying flow physics in the areas of turbulence, aerodynamics, hydrodynamics, convective heat transfer, combustion, turbomachinery, multi-phase flows, and chemical, biological and geological flows. In addition, readers will find papers that report on investigations combining experimental and analytical/numerical approaches.
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