Sound Localization Method Using Modified SRP-PHAT Algorithm

Tan Ying; Yin Fu-liang; Li Xi-lin

Volume 28 Issue 7

Jan. 2011

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Article Navigation > Journal of Electronics & Information Technology > 2006 > 28(7): 1223-1227

Tan Ying, Yin Fu-liang, Li Xi-lin. Sound Localization Method Using Modified SRP-PHAT Algorithm[J]. Journal of Electronics & Information Technology, 2006, 28(7): 1223-1227.

Citation:

Tan Ying, Yin Fu-liang, Li Xi-lin. Sound Localization Method Using Modified SRP-PHAT Algorithm[J]. Journal of Electronics & Information Technology, 2006, 28(7): 1223-1227.

Tan Ying, Yin Fu-liang, Li Xi-lin. Sound Localization Method Using Modified SRP-PHAT Algorithm[J]. Journal of Electronics & Information Technology, 2006, 28(7): 1223-1227.

Citation:

Tan Ying, Yin Fu-liang, Li Xi-lin. Sound Localization Method Using Modified SRP-PHAT Algorithm[J]. Journal of Electronics & Information Technology, 2006, 28(7): 1223-1227.

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Sound Localization Method Using Modified SRP-PHAT Algorithm

Received Date: 2004-08-13
Rev Recd Date: 2006-03-31
Publish Date: 2006-07-19

Abstract

Abstract

A method, which combines Steered Response Power with PHAse Transform (SRP-PHAT), is a robust speech localization approach with microphone arrays. A relatively precise direction of arrival (DOA) estimation can be achieved by using it in the environment of weak noise and moderate reverberation. However, the localization performance degrades sharply in the environment of low SNR and strong reverberation. Moreover, a real-time localization system is also difficult to be realized due to its heavy computation load. Aiming at these problems, a modified SRP-PHAT localization algorithm is proposed in order to improve the performance of speech localization system. The modified SRP-PHAT algorithm reduces computation load greatly. The results of simulation experiment indicate that the proposed method gives higher localization precision even in an environment of low SNR and strong reverberation.

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References(1)

References

Wang Qinghua, Ivanov T, Aarabi P. Acoustic Robot Navigation using Distributed Microphone Arrays[J].Information Fusion.2004, Vol.5:131-140[2]Potamitis I, Chen Huimin, Tremoulis G. Tracking of Multiple Moving Speakers with Multiple Microphone Arrays[J].IEEE Trans. on speech and audio processing.2004, 12(5):520-[3]Brandstein M. A framework for speech source localization using sensor arrays. Doctoral Dissertation, Brown University, May 1995.[4]DiBiase J. A high-accuracy, low-latency technique for talker localization in reverberant environments. PhD thesis, Brown University, Providence RI, USA, May 2000.[5]Kinsler L.[J].Frey A, Coppens A, Sanders J. Fundamentals of Acoustics. Third edition, New York: John Wiley Sons.1982,:-[6]Ziomaek L. Fundamentals of Acoustic Field Theory and Space-Time Signal Processing. Boca Raton, FL: CRC Press, 1995: 210－248.[7]Huang Jie, Ohnishi N, Sugie N. Modeling the precedence effect for sound localization in reverberant environment. IEEE Instrumentation and Measurement Technology Conference, Brussels, June 1996: 633－636.[8]Svaizer P, Matassoni M, Omologo M. Acoustic source location in a three-dimensional space using crosspower spectrum phase. in Proc. IEEE Int. Conf. Acoust.，Speech, Signal Processing (ICASSP-97), Munich, Germany, April 1997:231－234.[9]Hahn W, Tretter S. Optimum processing for delay vector estimation in passive signal arrays[J].IEEE Trans. on Information Theory.1973, 19 (1):608-[10]Allen J B, Berkley D A. Image method for efficiently simulating small room acoustics[J].Journal of Acoustical Society of America.1979, 65(4):943-[11]Brandstein M, Adcock J, Silverman H. Microphone array localization error estimation with application to sensor placement. J. Acoust. Soc. Am., April 1997, 99(6): 251－254.

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