Estimation of the Optimal Spherical Harmonics Order for the Interpolation of Head-Related Transfer Functions Sampled on Sparse Irregular Grids

IF 1.3 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Frontiers in signal processing Pub Date : 2022-09-30 DOI:10.3389/frsip.2022.884541
David Bau, Johannes M. Arend, C. Pörschmann
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引用次数: 1

Abstract

Conventional individual head-related transfer function (HRTF) measurements are demanding in terms of measurement time and equipment. For more flexibility, free body movement (FBM) measurement systems provide an easy-to-use way to measure full-spherical HRTF datasets with less effort. However, having no fixed measurement installation implies that the HRTFs are not sampled on a predefined regular grid but rely on the individual movements of the subject. Furthermore, depending on the measurement effort, a rather small number of measurements can be expected, ranging, for example, from 50 to 150 sampling points. Spherical harmonics (SH) interpolation has been extensively studied recently as one method to obtain full-spherical datasets from such sparse measurements, but previous studies primarily focused on regular full-spherical sampling grids. For irregular grids, it remains unclear up to which spatial order meaningful SH coefficients can be calculated and how the resulting interpolation error compares to regular grids. This study investigates SH interpolation of selected irregular grids obtained from HRTF measurements with an FBM system. Intending to derive general constraints for SH interpolation of irregular grids, the study analyzes how the variation of the SH order affects the interpolation results. Moreover, the study demonstrates the importance of Tikhonov regularization for SH interpolation, which is popular for solving ill-posed numerical problems associated with such irregular grids. As a key result, the study shows that the optimal SH order that minimizes the interpolation error depends mainly on the grid and the regularization strength but is almost independent of the selected HRTF set. Based on these results, the study proposes to determine the optimal SH order by minimizing the interpolation error of a reference HRTF set sampled on the sparse and irregular FBM grid. Finally, the study verifies the proposed method for estimating the optimal SH order by comparing interpolation results of irregular and equivalent regular grids, showing that the differences are small when the SH interpolation is optimally parameterized.
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稀疏不规则网格上采样头相关传递函数插值的最优球谐阶估计
传统的个体头部相关传递函数(HRTF)测量在测量时间和设备方面要求很高。为了获得更大的灵活性,自由体运动(FBM)测量系统提供了一种易于使用的方法来测量全球面HRTF数据集。然而,没有固定的测量装置意味着hrtf不是在预定义的规则网格上采样,而是依赖于受试者的个人运动。此外,根据测量工作的不同,可以预期相当少量的测量,例如从50到150个采样点不等。球面谐波(SH)插值作为从稀疏测量中获得全球面数据集的一种方法,近年来得到了广泛的研究,但以往的研究主要集中在规则的全球面采样网格上。对于不规则网格,目前还不清楚可以计算到哪个空间顺序有意义的SH系数,以及与规则网格相比,由此产生的插值误差如何。本文研究了用FBM系统对从HRTF测量中获得的选定不规则网格进行SH插值。为了推导出不规则网格SH插值的一般约束条件,分析了SH阶的变化对插值结果的影响。此外,该研究还证明了Tikhonov正则化对SH插值的重要性,这是解决与此类不规则网格相关的病态数值问题的流行方法。研究的一个关键结果是,最小化插值误差的最优SH顺序主要取决于网格和正则化强度,而几乎与所选择的HRTF集无关。基于这些结果,本研究提出了通过最小化参考HRTF集在稀疏和不规则FBM网格上采样的插值误差来确定最优SH顺序。最后,通过对不规则网格和等效规则网格插值结果的比较,验证了所提方法的最优SH阶估计方法,结果表明,在最优参数化SH阶插值时,两者之间的差异很小。
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