Acoustic Analogy with High-Order Time Derivatives for Far-Field Acoustic Predictions

IF 0.9 4区物理与天体物理 Q4 ACOUSTICS

Acoustical Physics Pub Date : 2024-02-28 DOI:10.1134/S106377102210013X

Minjun Park, Hakjin Lee

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Abstract

The numerical method is proposed for predicting the far-field noise using Ffowcs Williams–Hawkings (FW–H) equation with high-order finite-difference method for the time derivative. The results of this method for second-, fourth-, and sixth-order finite difference approximations are compared with that of analytic applications, such as monopole and dipole. It is observed that the use of the high-order time derivatives is an efficient approach to improve the prediction accuracy of the radiated acoustic pressure, particularly when the temporal resolution is not sufficiently high owing to the limited time step size. Our findings in this study provide evidence that for higher-order approximations, the RMS error for the first and second derivatives is smaller. In addition, the RMS error for the sixth-order approximation decreases considerably compared to that for the second-order approximation, with an increase in the number of points per period. This study and its results are expected to serve as a guide for noise prediction, indicating the temporal accuracies of the acoustic analogy according to the high-order approximation of time derivatives.

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声学类比与远场声学预测的高阶时间导数

摘要利用 Ffowcs Williams-Hawkings (FW-H) 方程和高阶有限差分法的时间导数，提出了预测远场噪声的数值方法。该方法的二阶、四阶和六阶有限差分近似结果与单极和偶极等分析应用的结果进行了比较。结果表明，使用高阶时间导数是提高辐射声压预测精度的有效方法，尤其是当时间分辨率因时间步长有限而不够高时。本研究的结果证明，对于高阶近似值，一阶和二阶导数的均方根误差较小。此外，与二阶近似相比，六阶近似的均方根误差随着每周期点数的增加而显著减小。这项研究及其结果有望为噪声预测提供指导，表明根据时间导数的高阶近似值进行声学类比的时间精确性。

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来源期刊

Acoustical Physics 物理-声学

CiteScore

1.60

自引率

50.00%

发文量

审稿时长

3.5 months

期刊介绍： Acoustical Physics is an international peer reviewed journal published with the participation of the Russian Academy of Sciences. It covers theoretical and experimental aspects of basic and applied acoustics: classical problems of linear acoustics and wave theory; nonlinear acoustics; physical acoustics; ocean acoustics and hydroacoustics; atmospheric and aeroacoustics; acoustics of structurally inhomogeneous solids; geological acoustics; acoustical ecology, noise and vibration; chamber acoustics, musical acoustics; acoustic signals processing, computer simulations; acoustics of living systems, biomedical acoustics; physical principles of engineering acoustics. The journal publishes critical reviews, original articles, short communications, and letters to the editor. It covers theoretical and experimental aspects of basic and applied acoustics. The journal welcomes manuscripts from all countries in the English or Russian language.