基于均衡和信号融合的身体传导语音增强

IEEE Transactions on Audio Speech and Language Processing Pub Date : 2013-12-01 DOI:10.1109/TASL.2013.2274696

Tomas Dekens, W. Verhelst

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引用次数: 14

摘要

本文从噪声鲁棒性语音处理的角度对体传导语音进行了研究。由于身体传导的语音通常受带宽限制，因此需要对信号进行处理以获得高质量和低噪声的信号。我们提出了一种算法，该算法首先使用从预定义滤波器集获得的滤波器均衡身体传导的语音，然后使用最佳的干净语音幅度和相位估计器将该均衡信号与有噪声的传统麦克风信号融合。我们评估了采用传统近距离谈话和喉部麦克风相结合的均衡和融合技术。主观聆听测试表明，该方法成功地融合了传统信号的语音质量和喉部传声器信号的噪声鲁棒性。听力测试还表明，身体传导信号的加入可以改善单通道语音增强方法，而一组计算的客观信号质量测量证实了这些观察结果。

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Body Conducted Speech Enhancement by Equalization and Signal Fusion

This paper studies body-conducted speech for noise robust speech processing purposes. As body-conducted speech is typically limited in bandwidth, signal processing is required to obtain a signal that is both high in quality and low in noise. We propose an algorithm that first equalizes the body-conducted speech using filters obtained from a pre-defined filter set and subsequently fuses this equalized signal with a noisy conventional microphone signal using an optimal clean speech amplitude and phase estimator. We evaluated the proposed equalization and fusion technique using a combination of a conventional close-talk and a throat microphone. Subjective listening tests show that the proposed method successfully fuses the speech quality of the conventional signal and the noise robustness of the throat microphone signal. The listening tests also indicate that the inclusion of the body-conducted signal can improve single-channel speech enhancement methods, while a calculated set of objective signal quality measures confirm these observations.

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来源期刊

IEEE Transactions on Audio Speech and Language Processing 工程技术-工程：电子与电气

自引率

0.00%

发文量

审稿时长

24.0 months

期刊介绍： The IEEE Transactions on Audio, Speech and Language Processing covers the sciences, technologies and applications relating to the analysis, coding, enhancement, recognition and synthesis of audio, music, speech and language. In particular, audio processing also covers auditory modeling, acoustic modeling and source separation. Speech processing also covers speech production and perception, adaptation, lexical modeling and speaker recognition. Language processing also covers spoken language understanding, translation, summarization, mining, general language modeling, as well as spoken dialog systems.