R. Al‐Shaikh scite author profile

R. Al‐Shaikh

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Pennsylvania State University

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A neural-counting model based on physiological characteristics of the peripheral auditory system. V. Application to loudness estimation and intensity discrimination

Lachs

Al‐Shaikh

et al. 1984

IEEE Trans. Syst., Man, Cybern.

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s-The psychophysical properties of a multiple-channel neuralcounting model are investigated. Each channel represents. a peripheral afferent fiber (or a group of such fibers) and consists of a cascade of signal-processing transformations, each of which has a physiological correlate in the auditory system. The acoustic signal (which may be a pure tone or Gaussian noise) is passed by our mathematical construct through the following series of transformations: an outer-and middle-ear transmission function, an inner-ear multiple-pole linear-filter tuning mechanism, a nonlinear receptor saturation function, and a refractoriness-modified Poisson transduction mechanism (which leads to a sub-Poisson neural spike count). Spontaneous neural activity is independently incorporated into each channel by means of an additive refractoriness-modified Poisson process. A union process at a more distal center in the nervous system is generated by a parallel collection of such channels with a density (in frequency) determined by the cochlear mapping function. The statistics of the union count (in a fixed time) are then processed at a decision center in a manner that depends on the psychophysical paradigm under consideration. This random count number is assumed to contain all of the information for the examples we consider. Our model has been used to calculate psychophysical functions for the following paradigms: pure-tone loudness estimation, pure-tone and variable-bandwidth noise intensity discrimination, and variable-bandwidth noise loudness summation. The theoretical results, which are determined in large part by spread of excitation, are in good agreement with human psychophysical data, provided that the parameters of the theoretical model are appropriately chosen. It has been found that a suitable choice of parameters is both physiologically sensible and self-consistent. As a further indication of the consistency of the model, the same general parametric dependencies as neurophysiological isointensity contours for peripheral afferent fibers in the squirrel monkey are exhibited by the single-channel theoretical count mean, which is calculated as a function Manuscript .of stimulus level and frequency. The single-channel count mean-to-variance ratio is in accord with laboratory data. Finally, the roles of the various components comprising our theoretical system are discussed, and our model is compared with related constructs.

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A neural-counting model based on physiological characteristics of the peripheral auditory system: Application to loudness estimation and intensity discrimination

Lachs

Al‐Shaikh

et al. 1983

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We have previously used an energy-based neural-counting model, incorporating spread of excitation, receptor saturation, spontaneous neural activity, and refractoriness in the primary auditory fibers, to predict the outcome of a number of neurophysiological and psychoacoustical experiments [M. C. Teich, et al., J. Acoust. Soc. Am. Suppl. 1 71, S18 (1982); G. Lachs et al., IEEE Trans. Syst., Man. Cybern. SMC-13, No. 5 (1983)]. We wish also to incorporate the frequency characteristics of the middle-ear transmission function, and the cochlear mapping function. This places a number of constraints on the allowed parameters of the theory. We discuss the parameter values required for our theoretical system to effectively predict the outcome of loudness-estimation and intensity-discrimination experiments, both for pure-tone and variable-bandwidth noise stimuli. [Work supported by NSF.]

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R. Al‐Shaikh

A neural-counting model based on physiological characteristics of the peripheral auditory system. V. Application to loudness estimation and intensity discrimination

A neural-counting model based on physiological characteristics of the peripheral auditory system: Application to loudness estimation and intensity discrimination

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