Literature DB >> 25480061

Sound pressure distribution within natural and artificial human ear canals: forward stimulation.

Michael E Ravicz1, Jeffrey Tao Cheng1, John J Rosowski1.   

Abstract

This work is part of a study of the interaction of sound pressure in the ear canal (EC) with tympanic membrane (TM) surface displacement. Sound pressures were measured with 0.5-2 mm spacing at three locations within the shortened natural EC or an artificial EC in human temporal bones: near the TM surface, within the tympanic ring plane, and in a plane transverse to the long axis of the EC. Sound pressure was also measured at 2-mm intervals along the long EC axis. The sound field is described well by the size and direction of planar sound pressure gradients, the location and orientation of standing-wave nodal lines, and the location of longitudinal standing waves along the EC axis. Standing-wave nodal lines perpendicular to the long EC axis are present on the TM surface >11-16 kHz in the natural or artificial EC. The range of sound pressures was larger in the tympanic ring plane than at the TM surface or in the transverse EC plane. Longitudinal standing-wave patterns were stretched. The tympanic-ring sound field is a useful approximation of the TM sound field, and the artificial EC approximates the natural EC.

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Year:  2014        PMID: 25480061      PMCID: PMC4257973          DOI: 10.1121/1.4898420

Source DB:  PubMed          Journal:  J Acoust Soc Am        ISSN: 0001-4966            Impact factor:   1.840


  30 in total

1.  Revision of estimates of acoustic energy reflectance at the human eardrum.

Authors:  M R Stinson
Journal:  J Acoust Soc Am       Date:  1990-10       Impact factor: 1.840

2.  Ear canal cross-sectional pressure distributions: mathematical analysis and computation.

Authors:  R D Rabbitt; M T Friedrich
Journal:  J Acoust Soc Am       Date:  1991-05       Impact factor: 1.840

3.  Phenomenological characterization of eardrum transduction.

Authors:  C A Shera; G Zweig
Journal:  J Acoust Soc Am       Date:  1991-07       Impact factor: 1.840

4.  Comparison between intensity and pressure as measures of sound level in the ear canal.

Authors:  S T Neely; M P Gorga
Journal:  J Acoust Soc Am       Date:  1998-11       Impact factor: 1.840

5.  Cadaver middle ears as models for living ears: comparisons of middle ear input immittance.

Authors:  J J Rosowski; P J Davis; S N Merchant; K M Donahue; M D Coltrera
Journal:  Ann Otol Rhinol Laryngol       Date:  1990-05       Impact factor: 1.547

6.  Estimation of eardrum acoustic pressure and of ear canal length from remote points in the canal.

Authors:  J C Chan; C D Geisler
Journal:  J Acoust Soc Am       Date:  1990-03       Impact factor: 1.840

7.  External and middle ear sound pressure distribution and acoustic coupling to the tympanic membrane.

Authors:  Christopher Bergevin; Elizabeth S Olson
Journal:  J Acoust Soc Am       Date:  2014-03       Impact factor: 1.840

8.  Specification of the geometry of the human ear canal for the prediction of sound-pressure level distribution.

Authors:  M R Stinson; B W Lawton
Journal:  J Acoust Soc Am       Date:  1989-06       Impact factor: 1.840

9.  Ear-canal impedance and reflection coefficient in human infants and adults.

Authors:  D H Keefe; J C Bulen; K H Arehart; E M Burns
Journal:  J Acoust Soc Am       Date:  1993-11       Impact factor: 1.840

10.  Measurement of umbo vibration in human subjects--method and possible clinical applications.

Authors:  R L Goode; G Ball; S Nishihara
Journal:  Am J Otol       Date:  1993-05
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  8 in total

1.  The Effect of Ear Canal Orientation on Tympanic Membrane Motion and the Sound Field Near the Tympanic Membrane.

Authors:  Jeffrey Tao Cheng; Michael Ravicz; Jérémie Guignard; Cosme Furlong; John J Rosowski
Journal:  J Assoc Res Otolaryngol       Date:  2015-04-25

2.  Tympanic membrane surface motions in forward and reverse middle ear transmissions.

Authors:  Jeffrey Tao Cheng; Nima Maftoon; Jérémie Guignard; Michael E Ravicz; John Rosowski
Journal:  J Acoust Soc Am       Date:  2019-01       Impact factor: 1.840

3.  Sound pressure distribution within human ear canals: II. Reverse mechanical stimulation.

Authors:  Michael E Ravicz; Jeffrey Tao Cheng; John J Rosowski
Journal:  J Acoust Soc Am       Date:  2019-03       Impact factor: 1.840

4.  Finite-Element Modelling of the Acoustic Input Admittance of the Newborn Ear Canal and Middle Ear.

Authors:  Hamid Motallebzadeh; Nima Maftoon; Jacob Pitaro; W Robert J Funnell; Sam J Daniel
Journal:  J Assoc Res Otolaryngol       Date:  2016-10-07

5.  Transaural experiments and a revised duplex theory for the localization of low-frequency tones.

Authors:  William M Hartmann; Brad Rakerd; Zane D Crawford; Peter Xinya Zhang
Journal:  J Acoust Soc Am       Date:  2016-02       Impact factor: 1.840

6.  Procedures for ambient-pressure and tympanometric tests of aural acoustic reflectance and admittance in human infants and adults.

Authors:  Douglas H Keefe; Lisa L Hunter; M Patrick Feeney; Denis F Fitzpatrick
Journal:  J Acoust Soc Am       Date:  2015-12       Impact factor: 1.840

7.  Response of the human tympanic membrane to transient acoustic and mechanical stimuli: Preliminary results.

Authors:  Payam Razavi; Michael E Ravicz; Ivo Dobrev; Jeffrey Tao Cheng; Cosme Furlong; John J Rosowski
Journal:  Hear Res       Date:  2016-02-12       Impact factor: 3.208

8.  In Situ Characterization of Micro-Vibration in Natural Latex Membrane Resembling Tympanic Membrane Functionally Using Optical Doppler Tomography.

Authors:  Daewoon Seong; Jaehwan Kwon; Deokmin Jeon; Ruchire Eranga Wijesinghe; Jaeyul Lee; Naresh Kumar Ravichandran; Sangyeob Han; Junsoo Lee; Pilun Kim; Mansik Jeon; Jeehyun Kim
Journal:  Sensors (Basel)       Date:  2019-12-20       Impact factor: 3.576
  8 in total

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