头部相关传递函数测量系统中相邻声源间的多重散射

IF 0.9 Q4 ACOUSTICS

Sound and Vibration Pub Date : 2019-01-01 DOI:10.32604/sv.2019.04644

Guang-zheng Yu, Yu Liu, Bo-sun Xie, Huali Zhou

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引用次数: 0

摘要

为了加速头部相关传递函数(HRTFs)的测量，通常在测量系统中使用两个或多个独立声源。但是相邻声源之间的多重散射会影响测量的精度。另一方面，声源的指向性也会引起测量误差。为此，提出了一种由两个近似全指向性球形声源和一个刚性球形头组成的模型来评估声源间多重散射引起的HRTF测量误差。用多极再展开分析的实例表明，在20 kHz频率下，当声源半径不超过0.025 m，声源相对于头部中心的距离不小于0.5 m，相邻两个声源的角距不小于20度时，同侧HRTFs的误差在±1.0 dB范围内。利用这种计算方法也可以对不同条件下的相似结论进行分析和讨论。此外，通过测量刚性球体和KEMAR人工头的HRTFs，验证了结果。

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Multiple Scattering Between Adjacent Sound Sources in Head-Related Transfer Function Measurement System

To accelerate head-related transfer functions (HRTFs) measurement, two or more independent sound sources are usually employed in the measurement system. However, the multiple scattering between adjacent sound sources may influence the accuracy of measurement. On the other hand, the directivity of sound source could induce measurement error. Therefore, a model consisting of two spherical sound sources with approximate omni-directivity and a rigid-spherical head is proposed to evaluate the errors in HRTF measurement caused by multiple scattering between sources. An example of analysis using multipole re-expansion indicates that the error of ipsilateral HRTFs are within the bound of ± 1.0 dB below a frequency of 20 kHz, provided that the sound source radius does not exceed 0.025 m, the source distance relative to head center is not less than 0.5 m, and the angular interval between two adjacent sources is not less than 20 degrees. Similar conclusions under different conditions can also be analyzed and discussed by using this calculation method. Furthermore, the results are verified by measurements of HRTFs for a rigid sphere and a KEMAR artificial head.

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来源期刊

Sound and Vibration 物理-工程：机械

CiteScore

1.50

自引率

33.30%

发文量

审稿时长

>12 weeks

期刊介绍： Sound & Vibration is a journal intended for individuals with broad-based interests in noise and vibration, dynamic measurements, structural analysis, computer-aided engineering, machinery reliability, and dynamic testing. The journal strives to publish referred papers reflecting the interests of research and practical engineering on any aspects of sound and vibration. Of particular interest are papers that report analytical, numerical and experimental methods of more relevance to practical applications. Papers are sought that contribute to the following general topics: -broad-based interests in noise and vibration- dynamic measurements- structural analysis- computer-aided engineering- machinery reliability- dynamic testing