@InProceedings{7760319,
  author = {S. Hafezi and A. H. Moore and P. A. Naylor},
  booktitle = {2016 24th European Signal Processing Conference (EUSIPCO)},
  title = {Multiple source localization in the spherical harmonic domain using augmented intensity vectors based on grid search},
  year = {2016},
  pages = {602-606},
  abstract = {Multiple source localization is an important task in acoustic signal processing with applications including dereverberation, source separation, source tracking and environment mapping. When using spherical microphone arrays, it has been previously shown that Pseudo-intensity Vectors (PIV), and Augmented Intensity Vectors (AIV), are an effective approach for direction of arrival estimation of a sound source. In this paper, we evaluate AIV-based localization in acoustic scenarios involving multiple sound sources. Simulations are conducted where the number of sources, their angular separation and the reverberation time of the room are varied. The results indicate that AIV outperforms PIV and Steered Response Power (SRP) with an average accuracy between 5 and 10 degrees for sources with angular separation of 30 degrees or more. AIV also shows better robustness to reverberation time than PIV and SRP.},
  keywords = {acoustic signal processing;direction-of-arrival estimation;harmonics;reverberation;search problems;source separation;steered response power;angular separation;direction of arrival estimation;PIV;AIV-based localization;Pseudo-intensity vector;spherical microphone array;environment mapping applications;source tracking applications;source separation applications;dereverberation applications;acoustic signal processing;grid search;augmented intensity vector;spherical harmonic domain;multiple source localization;Direction-of-arrival estimation;Harmonic analysis;Smoothing methods;Microphone arrays;Array signal processing;Reverberation;spherical microphone arrays;localization;direction-of-arrival estimation;spherical harmonic;intensity vector},
  doi = {10.1109/EUSIPCO.2016.7760319},
  issn = {2076-1465},
  month = {Aug},
  url = {https://www.eurasip.org/proceedings/eusipco/eusipco2016/papers/1570251800.pdf},
}

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A."],"year":2016,"bibtype":"inproceedings","biburl":"https://raw.githubusercontent.com/Roznn/EUSIPCO/main/eusipco2016url.bib","bibdata":{"bibtype":"inproceedings","type":"inproceedings","author":[{"firstnames":["S."],"propositions":[],"lastnames":["Hafezi"],"suffixes":[]},{"firstnames":["A.","H."],"propositions":[],"lastnames":["Moore"],"suffixes":[]},{"firstnames":["P.","A."],"propositions":[],"lastnames":["Naylor"],"suffixes":[]}],"booktitle":"2016 24th European Signal Processing Conference (EUSIPCO)","title":"Multiple source localization in the spherical harmonic domain using augmented intensity vectors based on grid search","year":"2016","pages":"602-606","abstract":"Multiple source localization is an important task in acoustic signal processing with applications including dereverberation, source separation, source tracking and environment mapping. When using spherical microphone arrays, it has been previously shown that Pseudo-intensity Vectors (PIV), and Augmented Intensity Vectors (AIV), are an effective approach for direction of arrival estimation of a sound source. In this paper, we evaluate AIV-based localization in acoustic scenarios involving multiple sound sources. Simulations are conducted where the number of sources, their angular separation and the reverberation time of the room are varied. The results indicate that AIV outperforms PIV and Steered Response Power (SRP) with an average accuracy between 5 and 10 degrees for sources with angular separation of 30 degrees or more. AIV also shows better robustness to reverberation time than PIV and SRP.","keywords":"acoustic signal processing;direction-of-arrival estimation;harmonics;reverberation;search problems;source separation;steered response power;angular separation;direction of arrival estimation;PIV;AIV-based localization;Pseudo-intensity vector;spherical microphone array;environment mapping applications;source tracking applications;source separation applications;dereverberation applications;acoustic signal processing;grid search;augmented intensity vector;spherical harmonic domain;multiple source localization;Direction-of-arrival estimation;Harmonic analysis;Smoothing methods;Microphone arrays;Array signal processing;Reverberation;spherical microphone arrays;localization;direction-of-arrival estimation;spherical harmonic;intensity vector","doi":"10.1109/EUSIPCO.2016.7760319","issn":"2076-1465","month":"Aug","url":"https://www.eurasip.org/proceedings/eusipco/eusipco2016/papers/1570251800.pdf","bibtex":"@InProceedings{7760319,\n author = {S. Hafezi and A. H. Moore and P. A. Naylor},\n booktitle = {2016 24th European Signal Processing Conference (EUSIPCO)},\n title = {Multiple source localization in the spherical harmonic domain using augmented intensity vectors based on grid search},\n year = {2016},\n pages = {602-606},\n abstract = {Multiple source localization is an important task in acoustic signal processing with applications including dereverberation, source separation, source tracking and environment mapping. When using spherical microphone arrays, it has been previously shown that Pseudo-intensity Vectors (PIV), and Augmented Intensity Vectors (AIV), are an effective approach for direction of arrival estimation of a sound source. In this paper, we evaluate AIV-based localization in acoustic scenarios involving multiple sound sources. Simulations are conducted where the number of sources, their angular separation and the reverberation time of the room are varied. The results indicate that AIV outperforms PIV and Steered Response Power (SRP) with an average accuracy between 5 and 10 degrees for sources with angular separation of 30 degrees or more. 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