Teaching machines on snoring: A benchmark on computer audition for snore sound excitation localisation

Kun Qian; Christoph Janott; Zixing Zhang; Jun Deng; Alice Baird; Clemens Heiser; Winfried Hohenhorst; Michael Herzog; Werner Hemmert; Björn Schuller

doi:10.24425/123918

Teaching machines on snoring: A benchmark on computer audition for snore sound excitation localisation

Kun Qian
, Christoph Janott
, Zixing Zhang
, Jun Deng
, Alice Baird
, Clemens Heiser
, Winfried Hohenhorst
, Michael Herzog
, Werner Hemmert
, Björn Schuller

Technical University of Munich
University Hospital Augsburg
Imperial College London
audEERING GmbH
Alfried Krupp Krankenhaus
Carl-Thiem-Klinikum

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

This paper proposes a comprehensive study on machine listening for localisation of snore sound excitation. Here we investigate the effects of varied frame sizes, and overlap of the analysed audio chunk for extracting low-level descriptors. In addition, we explore the performance of each kind of feature when it is fed into varied classifier models, including support vector machines, k-nearest neighbours, linear discriminant analysis, random forests, extreme learning machines, kernel-based extreme learning machines, multilayer perceptrons, and deep neural networks. Experimental results demonstrate that, wavelet packet transform energy can outperform most other features. A deep neural network trained with subband energy ratios reaches the highest performance achieving an unweighted average recall of 72.8% from four types for snoring.

Original language	English
Pages (from-to)	465-475
Number of pages	11
Journal	Archives of Acoustics
Volume	43
Issue number	3
DOIs	https://doi.org/10.24425/123918
State	Published - 2018

Keywords

Acoustic features
Machine learning
Obstructive sleep apnea
Snore sound

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10.24425/123918

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title = "Teaching machines on snoring: A benchmark on computer audition for snore sound excitation localisation",

abstract = "This paper proposes a comprehensive study on machine listening for localisation of snore sound excitation. Here we investigate the effects of varied frame sizes, and overlap of the analysed audio chunk for extracting low-level descriptors. In addition, we explore the performance of each kind of feature when it is fed into varied classifier models, including support vector machines, k-nearest neighbours, linear discriminant analysis, random forests, extreme learning machines, kernel-based extreme learning machines, multilayer perceptrons, and deep neural networks. Experimental results demonstrate that, wavelet packet transform energy can outperform most other features. A deep neural network trained with subband energy ratios reaches the highest performance achieving an unweighted average recall of 72.8\% from four types for snoring.",

keywords = "Acoustic features, Machine learning, Obstructive sleep apnea, Snore sound",

author = "Kun Qian and Christoph Janott and Zixing Zhang and Jun Deng and Alice Baird and Clemens Heiser and Winfried Hohenhorst and Michael Herzog and Werner Hemmert and Bj{\"o}rn Schuller",

note = "Publisher Copyright: Copyright {\textcopyright} 2018 by PAN – IPPT.",

year = "2018",

doi = "10.24425/123918",

language = "English",

volume = "43",

pages = "465--475",

journal = "Archives of Acoustics",

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TY - JOUR

T1 - Teaching machines on snoring

T2 - A benchmark on computer audition for snore sound excitation localisation

AU - Qian, Kun

AU - Janott, Christoph

AU - Zhang, Zixing

AU - Deng, Jun

AU - Baird, Alice

AU - Heiser, Clemens

AU - Hohenhorst, Winfried

AU - Herzog, Michael

AU - Hemmert, Werner

AU - Schuller, Björn

PY - 2018

Y1 - 2018

N2 - This paper proposes a comprehensive study on machine listening for localisation of snore sound excitation. Here we investigate the effects of varied frame sizes, and overlap of the analysed audio chunk for extracting low-level descriptors. In addition, we explore the performance of each kind of feature when it is fed into varied classifier models, including support vector machines, k-nearest neighbours, linear discriminant analysis, random forests, extreme learning machines, kernel-based extreme learning machines, multilayer perceptrons, and deep neural networks. Experimental results demonstrate that, wavelet packet transform energy can outperform most other features. A deep neural network trained with subband energy ratios reaches the highest performance achieving an unweighted average recall of 72.8% from four types for snoring.

AB - This paper proposes a comprehensive study on machine listening for localisation of snore sound excitation. Here we investigate the effects of varied frame sizes, and overlap of the analysed audio chunk for extracting low-level descriptors. In addition, we explore the performance of each kind of feature when it is fed into varied classifier models, including support vector machines, k-nearest neighbours, linear discriminant analysis, random forests, extreme learning machines, kernel-based extreme learning machines, multilayer perceptrons, and deep neural networks. Experimental results demonstrate that, wavelet packet transform energy can outperform most other features. A deep neural network trained with subband energy ratios reaches the highest performance achieving an unweighted average recall of 72.8% from four types for snoring.

KW - Acoustic features

KW - Machine learning

KW - Obstructive sleep apnea

KW - Snore sound

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ER -

Teaching machines on snoring: A benchmark on computer audition for snore sound excitation localisation

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Keywords

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