Authors: Yi Chao Ma, Cheng Siong Chin, Wai Lok Woo

Abstract:

Since the last decade, there has been a rapid growth in digital multimedia, such as high-resolution media files and threedimentional movies. Hence, there is a need for large digital storage such as Hard Disk Drive (HDD). As such, users expect to have a quieter HDD in their laptop. In this paper, a jury test has been conducted on a group of 34 people where 17 of them are students who are the potential consumer, and the remaining are engineers who know the HDD. A total 13 HDD sound samples have been selected from over hundred HDD noise recordings. These samples are selected based on an agreed subjective feeling. The samples are played to the participants using head acoustic playback system, which enabled them to experience as similar as possible the same environment as have been recorded. Analysis has been conducted and the obtained results have indicated different group has different perception over the noises. Two neural network-based acoustic annoyance models are established based on back propagation neural network. Four psychoacoustic metrics, loudness, sharpness, roughness and fluctuation strength, are used as the input of the model, and the subjective evaluation results are taken as the output. The developed models are reasonably accurate in simulating both training and test samples.

Keywords: Hard disk drive noise, jury test, neural network model, psychoacoustic annoyance.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1109413

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1493

References:

[1] R. H. Lyon, “Designing for Product Sound Quality”, Marcel Dekker, Inc. 2000.
[2] “Acoustic Measurement of Airborne Noise Emitted by Information Technology and Telecommunications Equipment”, BS EN ISO 7779:2001
[3] World Health Organization 1960 Constitution, Geneva: World Health Organization.
[4] Y. Osada, “An Overview of Health Effects of Noise”, J. Sound Vib. 127(3), 407-410. 1988.
[5] S. Choi, W. Moon, S. Gang, T. Hwang, “Human-Based Evaluation of Sound from Hard Disk Drives for Noise Control”, Microsyst. Technol. 10, 640-648 © Springer-Verlag 2004.
[6] Goshen, C E, “Noise, Annoyance, and Progress”, Science (New York, N. Y.), Vol. 144(3618), pp. 487, 1964.
[7] H. Fastl, E. Zwicker, “Psycho-Acoustics Facts and Models” 3rd edition, Springer (2007).
[8] R. H. Lyon, “Engineered Sound Quality Coupling Subjective Reactions to Engineering Choices”, (IEEE) Ind. Appl. Mag. Vol 6, Nov/Dec 2000.
[9] V. Kecman, “Learning and Soft Computing”, the MIT press (2001).
[10] W.L. Woo and S.S. Dlay, “Neural network approach to blind signal separation of mono-nonlinearly mixed signals”, (IEEE) Circuits and System I, 52(2), 1236-1247, 2005.
[11] W.L. Woo and S.S. Dlay, “Nonlinear Blind Source Separation Using a Hybrid RBF-FMLP Network”, (IEE) Vision, Image and Signal Processing, 152(2), 173-183, 2005.
[12] Bin Gao, W.L. Woo and L.C. Khor, “Cochleagram-Based Audio Pattern Separation Using Two-Dimensional Non-Negative Matrix Factorization with Automatic Sparsity Adaptation,” J. Acoust. Soc. Am., 135(3), 1171-1185, 2014.
[13] Bin Gao, W.L. Woo and S.S. Dlay, “Unsupervised Single Channel Separation of Non-Stationary Signals Using Gammatone Filterbank and Itakura-Saito Nonnegative Matrix Two-Dimensional Factorizations,” (IEEE) Circuits and Systems I, 60(3), 662-675, 2013.