Energy-Detection Model for Monaural Auditory Detection

Pfafflin, Sheila M.; Mathews, M. V.

doi:10.1121/1.1909139

Cited by 58 publications

(37 citation statements)

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“…In a negative masking paradigm an investigator examines the behavior of DX DL for levels of X close to absolute threshold. The pedestal effect is best demonstrated in plots relating proportion correct to pedestal level (Pfafflin and Mathews, 1962); a plot we call the fixed-signal function. If the level of a signal, DX, is held constant while X varies, and a performance index such as proportion correct is measured, then it has been found that the addition of a pedestal around threshold enables an observer to distinguish the fixed level DX with greater ease than if no pedestal had been present (Green, 1960(Green, , 1966Laming, 1986;Pfafflin and Mathews, 1962).…”

Section: Introductionmentioning

confidence: 99%

“…The pedestal effect is best demonstrated in plots relating proportion correct to pedestal level (Pfafflin and Mathews, 1962); a plot we call the fixed-signal function. If the level of a signal, DX, is held constant while X varies, and a performance index such as proportion correct is measured, then it has been found that the addition of a pedestal around threshold enables an observer to distinguish the fixed level DX with greater ease than if no pedestal had been present (Green, 1960(Green, , 1966Laming, 1986;Pfafflin and Mathews, 1962). The nonmonotonic form of the fixed-signal function is not accommodated by Weber's law, which stipulates that as X increases the difference between X and XþDX must increase proportionally to maintain a fixed level of performance.…”

Section: Introductionmentioning

confidence: 99%

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Masking functions and fixed-signal functions for low-level 1000-Hz tones

Shepherd

Hautus

Jesteadt

2013

The Journal of the Acoustical Society of America

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Masking functions and fixed-signal functions were constructed using a narrow range of pedestal intensities for 10-ms, 1000-Hz gated tones. Data from three experiments agreed with previously reported data, clearly demonstrating negative masking and the pedestal effect. The data extend earlier findings by showing (1) the resilience of the pedestal effect when a background noise masker is introduced; (2) a possible indifference of the fixed-signal function to stimulus duration; (3) the ability of a set of psychometric functions to produce both masking and fixed-signal functions; (4) depending on method, the impact of unit choice on the interpretation of both the pedestal effect and negative masking data. Results are discussed in relation to current psychophysical models, and suggest that accounting for the auditory system's sensitivity to differences in low-level sounds remains a challenge.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Masking functions and fixed-signal functions for low-level 1000-Hz tones

Shepherd

Hautus

Jesteadt

2013

The Journal of the Acoustical Society of America

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“…One is the detectability index for an energy detector. In this case, the detector is simply monitoring the energy in a band, W, with noise density, No, and trying to detect a potential signal of energy, E s ' and duration, T Pfaffiin and Mathews (1962) and Green and Swets (1966) have analyzed this case. To a good first approximation…”

Section: Inmentioning

confidence: 98%

Auditory Intensity Discrimination

Green¹

1993

Springer Handbook of Auditory Research

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“…Historically, however, theoretical predictions of perception have often overestimated the capabilities of the human auditory system. The discrepancies between theorctical and experimcntal results were commonly corrected by adding a Gaussian noise source to the system (e.g., [2]). Howevcr, as this procedure was not physiologically-based, the parameters of the noise sourcc had to be adjusted for each detection problem, reducing the generality of the approach.…”

Section: Introductionmentioning

confidence: 99%

“…+ t t > 0 (2). Since the functional mapping is strictly monotonic, the probability density function can he derived using the formula, where ti = t ; ( y ) and .q'(t;) # 0[ I 11.…”

mentioning

confidence: 99%

The effect of a Poisson "internal noise" process on theoretical acoustic signal detectability

Gresham

Collins²

Proceedings of the 1999 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics. WASPAA'99 (Cat. No.99TH8452)

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Historically, theoretical predictions of human auditory perception have not agreed with experimental measurements. We hive previously demonstratcd that using signal dctection theory to analyze the outputs of deterministic computalional auditory models yields morc accurate predictions of expcrimental performance than traditional approaches [I]. Howevcr, discrepancies remained between predicted and aclual pcrlormance. In this paper, the effccts of stimulus uncertainty and neural variability on the detectability of a tone in noise are studied. The results suggest that remarkably accurate predictions of detection performance can he generated when such uncertainty is incorporated into the problem.

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Energy-Detection Model for Monaural Auditory Detection

Cited by 58 publications

References 0 publications

Masking functions and fixed-signal functions for low-level 1000-Hz tones

Masking functions and fixed-signal functions for low-level 1000-Hz tones

Auditory Intensity Discrimination

The effect of a Poisson "internal noise" process on theoretical acoustic signal detectability

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