Deep learning techniques for noise annoyance detection: Results from an intensive workshop at the Alan Turing Institute-Reference-Cited by-同舟云学术

Deep learning techniques for noise annoyance detection: Results from an intensive workshop at the Alan Turing Institute

Published:2023-03-01 Issue:3_supplement Volume:153 Page:A262-A262
ISSN:0001-4966
Container-title:The Journal of the Acoustical Society of America
language:en
Short-container-title:

Author:

Mitchell Andrew¹,Brown Emmeline²,Deo Ratneel³,Hou Yuanbo⁴,Kirton-Wingate Jasper⁵,Liang Jinhua⁶,Sheinkman Alisa⁷,Soelistyo Christopher⁸,Sood Hari⁹,Wongprommoon Arin¹⁰,Xing Kaiyue¹¹,Yip Wingyan¹²,Aletta Francesco¹³

Affiliation:

1. Inst. for Environ. Design and Eng., Univ. College London (UCL), Central House, 14 Upper Woburn, London WC1H 0NN, United Kingdom, andrew.mitchell.18@ucl.ac.uk

2. Ctr. for Adv. Biomedical Imaging, Univ. College London (UCL), London, United Kingdom

3. Univ. of Sydney, Sydney, New South Wales, Australia

4. Faculty of Eng. and Architecture, Ghent Univ., Ghent, Belgium

5. COG-MHEAR, Edinburgh Napier Univ., London, United Kingdom

6. School of Electron. Eng. and Comput. Sci., Queen Mary Univ. of London, London, United Kingdom

7. School of Mathematics, Univ. of Edinburgh, Edinburgh, United Kingdom

8. Inst. for the Phys. of Living Systems, Univ. College London (UCL), London, United Kingdom

9. The Alan Turing Inst., London, United Kingdom

10. School of Informatics, Univ. of Edinburgh, Edinburgh, United Kingdom

11. School of Education, Commun., and Lang. Sci., Newcastle Univ., Newcastle, United Kingdom

12. Soldo, Ltd., London, United Kingdom

13. Inst. for Environ. Design and Eng., Univ. College London (UCL), London, United Kingdom

Abstract

Advancements in AI and ML have enabled us to combine automated sound source recognition and deep learning models for predicting subjective soundscape perception. We held a multidisciplinary, cross-institutional Data Study Group (DSG) to investigate how sound source information could be incorporated into deep learning models for predicting urban noise annoyance. We used a large-scale dataset of 2980 15-s recordings paired with 12 210 annoyance ratings (from 1 to 10) and sound source labels. A total of 14 neural networks and 4 conventional ML models were built. The best model was trained to simultaneously predict sound source labels and annoyance rating. It achieved an RMSE = 1.07 for annoyance prediction and AUROC = 0.88 for label classification, while a similarly structured model trained to predict annoyance ratings only (i.e., no sound source information) achieved RMSE = 1.13. Results showed that including sound source labels as a simultaneous training output, rather than as an explicit model input resulted in the best performance. Overall, these models performed very well at predicting both annoyance ratings and identifying sources, providing a starting bed for automated annoyance detection systems. This presentation will provide context for the DSG and present conclusions drawn regarding approaches to applying deep learning techniques to noise annoyance detection.

Publisher

Acoustical Society of America (ASA)

Subject

Acoustics and Ultrasonics,Arts and Humanities (miscellaneous)

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