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增强对语音基频的神经追踪

Enhanced Neural Tracking of the Fundamental Frequency of the Voice.

作者信息

Van Canneyt Jana, Wouters Jan, Francart Tom

出版信息

IEEE Trans Biomed Eng. 2021 Dec;68(12):3612-3619. doi: 10.1109/TBME.2021.3080123. Epub 2021 Nov 19.

DOI:10.1109/TBME.2021.3080123

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7616899/

Abstract

OBJECTIVE

'F0 tracking' is a novel method that investigates neural processing of the fundamental frequency of the voice (f0) in continuous speech. Using linear modelling, a feature that reflects the f0 of a presented speech stimulus is predicted from neural EEG responses. The correlation between the predicted and the 'actual' f0 feature is a measure for neural response strength. In this study, we aimed to design a new f0 feature that approximates the expected human EEG response to the f0 in order to improve neural tracking results.

METHODS

Two techniques were explored: constructing the feature with a phenomenological model to simulate neural processing in the auditory periphery and low-pass filtering the feature to approximate the effect of more central processing.

RESULTS

Analysis of EEG-data evoked by a Flemish story in 34 subjects indicated that both the auditory model and the low-pass filter significantly improved the correlations between the actual and reconstructed feature. The combination of both strategies almost doubled the mean correlation across subjects, from 0.078 to 0.13. Moreover, canonical correlation analysis revealed two distinct processes contributing to the f0 response: one driven by broad range of auditory nerve fibers with center frequency up to 8 kHz and one driven by a more narrow selection of auditory nerve fibers, possibly responding to unresolved harmonics.

CONCLUSION

Optimizing the f0 feature towards the expected neural response, significantly improves f0-tracking correlations.

SIGNIFICANCE

The optimized f0 feature enhances the f0-tracking method, facilitating future research on temporal auditory processing in the human brain.

摘要

目的

“F0跟踪”是一种研究连续语音中语音基频（f0）神经处理的新方法。通过线性建模，从神经脑电图反应中预测出反映所呈现语音刺激f0的特征。预测的f0特征与“实际”f0特征之间的相关性是神经反应强度的一种度量。在本研究中，我们旨在设计一种新的f0特征，使其接近人类脑电图对f0的预期反应，以改善神经跟踪结果。

方法

探索了两种技术：用现象学模型构建特征以模拟听觉外周的神经处理，以及对该特征进行低通滤波以近似更中枢处理的效果。

结果

对34名受试者听弗拉芒语故事诱发的脑电图数据进行分析表明，听觉模型和低通滤波器均显著提高了实际特征与重建特征之间的相关性。两种策略的结合使受试者的平均相关性几乎提高了一倍，从0.078提高到0.13。此外，典型相关分析揭示了对f0反应有贡献的两个不同过程：一个由中心频率高达8kHz的广泛听觉神经纤维驱动，另一个由更窄选择的听觉神经纤维驱动，可能对未解析的谐波作出反应。

结论

将f0特征优化为接近预期的神经反应，可显著提高f0跟踪相关性。

意义

优化后的f0特征增强了f0跟踪方法，便于未来对人类大脑时间听觉处理的研究。