Auditory filter nonlinearity at 2 kHz in normal hearing listeners

Stuart Rosen; Richard J. Baker; Angela Darling

Auditory filter nonlinearity at 2 kHz in normal hearing listeners

Stuart Rosen, Richard J. Baker, Angela Darling

Research output: Contribution to journal › Article › peer-review

Abstract

Auditory filters broaden with increasing level. Using a recently developed method of fitting filter shapes to notched-noise masking data that explicitly models the nonlinear changes in filter shape across level, results at 2 kHz from 9 listeners over a wide range of levels and notch widths are reported. Families of roex (p, w, t) filter shapes lead to models which account well for the observed data. The primary effect of level is a broadening in the tails of the filter as level increases. In all cases, models with filter parameters depending on probe level fit the data much better than masker-dependent models. Thus auditory filter shapes appear to be controlled by their output, not by their input. Notched-noise tests, if performed at a single level, should use a fixed probe level. Filter shapes derived in this way, and normalized to have equal tail gain, are highly reminiscent of measurements made directly on the basilar membrane, including the degree of compression evidenced in the input-output function.

Original language	English
Pages (from-to)	2539-2550
Number of pages	11
Journal	Journal of the Acoustical Society of America
Volume	103
Issue number	5 I
Publication status	Published - May 1998

Keywords

FREQUENCY-SELECTIVITY; NERVE-FIBERS; GUINEA-PIG; SHAPES;
RESPONSES; MASKING; RECOGNITION; PATTERNS; GROWTH

Cite this

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title = "Auditory filter nonlinearity at 2 kHz in normal hearing listeners",

abstract = "Auditory filters broaden with increasing level. Using a recently developed method of fitting filter shapes to notched-noise masking data that explicitly models the nonlinear changes in filter shape across level, results at 2 kHz from 9 listeners over a wide range of levels and notch widths are reported. Families of roex (p, w, t) filter shapes lead to models which account well for the observed data. The primary effect of level is a broadening in the tails of the filter as level increases. In all cases, models with filter parameters depending on probe level fit the data much better than masker-dependent models. Thus auditory filter shapes appear to be controlled by their output, not by their input. Notched-noise tests, if performed at a single level, should use a fixed probe level. Filter shapes derived in this way, and normalized to have equal tail gain, are highly reminiscent of measurements made directly on the basilar membrane, including the degree of compression evidenced in the input-output function.",

keywords = "FREQUENCY-SELECTIVITY; NERVE-FIBERS; GUINEA-PIG; SHAPES;, RESPONSES; MASKING; RECOGNITION; PATTERNS; GROWTH",

author = "Stuart Rosen and Baker, {Richard J.} and Angela Darling",

year = "1998",

month = may,

language = "English",

volume = "103",

pages = "2539--2550",

journal = "Journal of the Acoustical Society of America",

issn = "0001-4966",

publisher = "Acoustical Society of America",

number = "5 I",

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TY - JOUR

T1 - Auditory filter nonlinearity at 2 kHz in normal hearing listeners

AU - Rosen, Stuart

AU - Baker, Richard J.

AU - Darling, Angela

PY - 1998/5

Y1 - 1998/5

N2 - Auditory filters broaden with increasing level. Using a recently developed method of fitting filter shapes to notched-noise masking data that explicitly models the nonlinear changes in filter shape across level, results at 2 kHz from 9 listeners over a wide range of levels and notch widths are reported. Families of roex (p, w, t) filter shapes lead to models which account well for the observed data. The primary effect of level is a broadening in the tails of the filter as level increases. In all cases, models with filter parameters depending on probe level fit the data much better than masker-dependent models. Thus auditory filter shapes appear to be controlled by their output, not by their input. Notched-noise tests, if performed at a single level, should use a fixed probe level. Filter shapes derived in this way, and normalized to have equal tail gain, are highly reminiscent of measurements made directly on the basilar membrane, including the degree of compression evidenced in the input-output function.

AB - Auditory filters broaden with increasing level. Using a recently developed method of fitting filter shapes to notched-noise masking data that explicitly models the nonlinear changes in filter shape across level, results at 2 kHz from 9 listeners over a wide range of levels and notch widths are reported. Families of roex (p, w, t) filter shapes lead to models which account well for the observed data. The primary effect of level is a broadening in the tails of the filter as level increases. In all cases, models with filter parameters depending on probe level fit the data much better than masker-dependent models. Thus auditory filter shapes appear to be controlled by their output, not by their input. Notched-noise tests, if performed at a single level, should use a fixed probe level. Filter shapes derived in this way, and normalized to have equal tail gain, are highly reminiscent of measurements made directly on the basilar membrane, including the degree of compression evidenced in the input-output function.

KW - FREQUENCY-SELECTIVITY; NERVE-FIBERS; GUINEA-PIG; SHAPES;

KW - RESPONSES; MASKING; RECOGNITION; PATTERNS; GROWTH

M3 - Article

SN - 0001-4966

VL - 103

SP - 2539

EP - 2550

JO - Journal of the Acoustical Society of America

JF - Journal of the Acoustical Society of America

IS - 5 I

ER -

Auditory filter nonlinearity at 2 kHz in normal hearing listeners

Abstract

Keywords

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