Sage Journals: Discover world-class research

Abstract

A stochastic model is proposed to describe the perceptual processes that underlie the classification of complex multidimensional sounds, such as passive sonar signatures. The model is based on four assumptions: (1) complex sounds may be represented psychologically as points in a multidimensional perceptual space, (2) categories are represented theoretically as distributions in this space centered at ideal category members or prototype, (3) the category distributions determine the conditional stimulus probabilities and have multivariate Gaussian form, and (4) individual dimensions in the perceptual space may be weighted differentially to reflect a listener's attentional processes. To evaluate the model, two groups were tested in an eight-category classification task involving 16 simulated propeller cavitation sounds. A perceptual structure was determined for the sounds in a preliminary non-metric multidimensional scaling study. The two groups received category assignments that stressed different properties of the cavitation sounds. An observed confusion matrix was derived by fitting the model to the observed data. Overall, comparison of the obtained and theoretical data indicated that the model provides a reasonable description of how listeners classify complex simulated sonar sounds. The assumption that listeners can selectively and independently adjust the relative importance of the perceptual dimensions was also supported. The utility of the proposed model as a tool for the development of preprocessing aids and training programs for sonar operators is discussed.

Get full access to this article

View all access options for this article.

References

Albers, V. M. Underwater acoustics handbook II. University Park, PA: Pennsylvania State University Press, 1965.

Ballas, J. A. , and Howard, J. H., Jr. Two approaches to category representation in aural classification (Technical Report ONR-78-9). Washington, DC: The Catholic University Human Performance Laboratory, 1978.

Cermac, G. W. , and Cornillon, P. C. Multidimensional analysis of judgments about traffic noise. Journal of the Acoustical Society of America, 1976, 59, 1412–1450.

Durlach, N. I. , and Braida, L. D. Intensity perception. I. Preliminary theory of intensity resolution. Journal of the Acoustical Society of America, 1969, 46, 372–383.

Garner, W. The processing of information and structure. New York: Wiley, 1974.

Getty, D. J. , Swets, J. A. , Swets, J. B. , and Green, D. M. On the prediction of confusion matrices from similarity judgments. Perception & Psychophysics, 1979, 26, 1–19.

Goldstein, J. L. An optimum processor theory for the central formation of pitch of complex tones. Journal of the Acoustical Society of America, 1973, 54, 1496–1516.

Gravetter, F. , and Lockhead, G. R. Criterial range as a frame of reference for stimulus judgment. Psychological Review, 1973, 80, 203–216.

Gray, L. M. , and Greeley, D. S. Source level model for propeller blade rate radiation for the world's merchant fleet. Journal of the Acoustical Society of America, 1980, 67, 516–522.

10.

Grey, J. M. Multidimensional scaling of musical timbres. Journal of the Acoustical Society of America, 1977, 61, 1270–1277.

11.

Green, D. M. , and Birdsall, T. G. Detection and recognition. Psychological Review, 1978, 85, 192–206.

12.

Green, D. M. , and Swets, J. A. Signal detection theory and psychophysics. New York: Wiley, 1966.

13.

Howard, J. H., Jr. Psychophysical structure of eight complex underwater sounds. Journal of the Acoustical Society of America, 1977, 62, 149–156.

14.

Howard, J. H. Jr. , Ballas, J. A. , and Burgy, D. C. Feature extraction and decision processes in the classification of amplitude modulated noise patterns (Technical Report ONR-78-4). Washington, DC: The Catholic University Human Performance Laboratory, 1978.

15.

Kahneman, D. Attention and effort. Englewood Cliffs, NJ: Prentice-Hall, 1973.

16.

Kornbrot, D. E. Attention bands: Some implications for categorical judgment. British Journal of Mathematical and Statistical Psychology, 1980, 33, 1–16.

17.

Meisel, W. S. Computer-oriented approaches to pattern recognition. New York: Academic Press, 1972.

18.

Miller, J. R. , and Carterette, B. C. Perceptual space for musical structures. Journal of the Acoustical Society of America, 1975, 58, 711–720.

19.

Morgan, B. J. , Woodhead, M. M. , and Webster, J. C. On the recovery of physical dimensions of stimuli, using multidimensional scaling. Journal of the Acoustical Society of America, 1976, 60, 186–189.

20.

Null, C. H. , and Young, F. W. Auditory perception: Recommendations for computer assisted experimental paradigm. In D. J. Getty and J. H. Howard, Jr. (Eds.) Auditory and visual pattern recognition. Hillsdale, NJ: Erlbaum, 1981.

21.

Plomp, R. Aspects of tone sensation: A psychophysical study. New York: Academic Press, 1976.

22.

Posner, M. I. Abstraction and the process of recognition. In G. H. Bower and J. T. Spence (Eds.) The psychology of learning and motivation (Vol. 3). New York: Academic Press, 1969.

23.

Reed, S. K. Psychological processes in pattern recognition. New York: Academic Press, 1973.

24.

Sandusky, A. Memory processes and judgmen. In E. C. Carterette and M. P. Friedman (Eds.) Handbook of perception II: Psychophysical judgment and measurement. New York: Academic Press, 1974.

25.

Shepard, R. N. , and Podgorny, P. Cognitive processes that resemble perceptual processess. In W. K. Estes (Ed.) Handbook of learning and cognitive processess V: Human information processing. Hillsdale, NJ: Erlbaum, 1978.

26.

Takane, Y. , Young, F. W. , and de Leeuw, J. Nonmetric individual differences in multidimensional scaling: An alternating least squares method with optimal scaling features. Psychometrika, 1977, 42, 7–68.

27.

Torgerson, W. S. Theory and method of scaling. New York: Wiley, 1958.

Perception of Simulated Propeller Cavitation

Abstract

Get full access to this article

References