Citation for published version (APA): van Hengel, P. W. J. (1996). Emissions from cochlear modelling. Groningen: s.n.
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1 University of Groningen Emissions from cochlear modelling van Hengel, Pieter Willem Jan IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from it. Please check the document version below. Document Version Publisher's PDF, also known as Version of record Publication date: 1996 Link to publication in University of Groningen/UMCG research database Citation for published version (APA): van Hengel, P. W. J. (1996). Emissions from cochlear modelling. Groningen: s.n. Copyright Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons). Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Downloaded from the University of Groningen/UMCG research database (Pure): For technical reasons the number of authors shown on this cover page is limited to 10 maximum. Download date:
2 Part IV For the interested reader 93
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4 de Boer, E. (1981). \Short waves in three-dimensional cochlea models: Solution for a `block' model," Hear. Res. 4, 53{77. de Boer, E. (1995). \The \inverse problem" solved for a three-dimensional model of the cochlea. I. Analysis," J. Acoust. Soc. Am. 98, 896{903. Diependaal, R. (1988a). Nonlinear and Active Cochlear Models: Analysis and Solution Methods. PhD thesis, TU-Delft, Netherlands. Diependaal, R. (1988b). \Time domain solutions for 1d, 2d & 3d cochlear models," in: Cochlear Mechanisms. Structure, function, and models, edited by J. P. Wilson and D. T. Kemp (Plenum, New York) pp. 445{452. Diependaal, R. J., Duifhuis, H., Hoogstraten, H. W., and Viergever, M. A. (1987). \Numerical methods for solving one-dimensional cochlear models in the time domain," J. Acoust. Soc. Am. 82, 1655{1666. Diependaal, R. J., and Viergever, M. A. (1983). \Point-impedance characterization of the basilar membrane in a three-dimensional cochlea model," Hear. Res. 11, 33{40. Duifhuis, H., Hoogstraten, H. W., van Netten, S. M., Diependaal, R. J., and Bialek, W. (1985). \Modelling the cochlear partition with coupled Van der Pol oscillators," in: Peripheral Auditory Mechanisms, edited by J. B. Allen, J. L. Hall, A. E. Hubbard, S. T. Neely and A. Tubis (Springer, New York) pp. 290{297. Duifhuis, H. (1989). \Power-law nonlinearities: A review of some less familiar properties," in: Cochlear Mechanisms: Structure, Function and Models, edited by J. P. Wilson and D. T. Kemp (Plenum, New York) pp. 395{403. Dunnebier, E. A., Segenhout, J. M., Kalicharan, D., Jongebloed, W. L., Wit, H. P., and Albers, F. W. J. (1995). \Low-voltage eld-emission scanning electron microscopy of non-coated guinea-pig hair cell stereocilia," Hear. Res. 90, 139{ 148. Geisler, C. D. (1993). \A realizable cochlear model using feedback from motile outer hair cells," Hear. Res. 68, 253{262. Greenwood, D. D. (1990). \A cochlear frequency position function for several species - 29 years later," J. Acoust. Soc. Am. 87, 2592{2605. Greenwood, D. D. (1991). \Critical bandwidth and consonance in relation to cochlear frequency-position coordinates," Hear. Res. 54, 164{208. Guinan, J. J., and Giord, M. L. (1988). \Eects of electrical stimulation of eerent olivocochlear neurons on cat auditory-nerve bers," Hear. Res. 37, 29{46. Hall, J.. L. (1974). \Two-tone distortion products in a nonlinear model of the basilar membrane," J. Acoust. Soc. Am. 56, 1818{1823. Harding, G. W., Baggot, P. J., and Bohne, B. A. (1992). \Height changes in the organ of Corti after noise exposure," Hear. Res. 63, 26{36. Harris, F. P., Lonsbury-Martin, B. L., Stagner, B. B., Coats, A. C., and Martin, G. K. (1989). \Acoustic distortion products in humans: Systematic changes in amplitude as a function of f 2 =f 1 ratio," J. Acoust. Soc. Am. 85, 220{229. Jones, K., Tubis, A., Long, G. R., Burns, E. M., and Strickland, E. A. (1986). \Interactions among multiple spontaneous otoacoustic emissions," in: Peripheral Auditory Mechanisms, edited by J. B. Allen, J. L. Hall, A. Hubbard, S. T. Neely and A. Tubis (Springer-Verlag, Berlin) pp. 266{273. Kanis, L. J. (1995). Cochlear nonlinearity: A computational model of the cochlea 95
5 solved in the frequency domain. PhD thesis, University of Amsterdam, The Netherlands. Kemp, D. T. (1978). \Stimulated acoustic emissions from within the human auditory system," J. Acoust. Soc. Am. 64, 1386{1391. Kemp, D. T. (1979). \Evidence of mechanical nonlinearity and frequency selective wave amplication in the cochlea," Arc. Oto-Rhino-Laryngol. 224, 37{45. Kiang, N. Y. S., Liberman, M. C., and Sewell, W. F. (1986). \Single unit clues to cochlear mechanisms," Hear. Res. 22, 171{182. Kim, D. O., Molnar, C. E., and Matthews, J. W. (1980). \Cochlear mechanics: Nonlinear behavior in two-tone responses as reected in cochlear-nerve-ber responses and in ear canal sound pressure," J. Acoust. Soc. Am. 67, 1704{1721. Kohlloel, L. U. E. (1990). \Cochlear mechanics: Coiling eects (I, II) and the absorption equation (III)," Hear. Res. 49, 19{28. Kok, M. R., van Zanten, G. A., and Brocaar, M. P. (1993). \Aspects of spontaneous otoacoustic emissions in healthy newborns," Hear. Res. 69, 115{123. Kolston, P. J., Viergever, M. A., de Boer, E., and Diependaal, R. J. (1989). \Realistic mechanical tuning in a micromechanical cochlear model," J. Acoust. Soc. Am. 86, 133{140. Kolston, P. J. (1988). \Sharp mechanical tuning in a cochlear model without negative damping," J. Acoust. Soc. Am. 83, 1481{1487. Lim, D. J. (1986). \Functional structure of the organ of Corti: a review," Hear. Res. 22, 117{146. Lonsbury-Martin, B. L., Martin, G., Probst, R., and Coats, A. (1988). \Spontaneous otoacoustic emissions in a nonhuman primate. II. Cochlear anatomy," Hear. Res. 33, 69{94. Matthews, J. W., and Molnar, C. E. (1985). \Modeling intracochlear and ear canal distortion product (2f 1 0 f 2 )," in: Peripheral Auditory Mechanisms, edited by J. B. Allen, J. L. Hall, A. Hubbard, S. T. Neely and A. Tubis (Springer-Verlag, Berlin) pp. 258{265. Matthews, J. W. (1980). Mechanical modeling of nonlinear phenomena observed in the peripheral auditory system. PhD thesis, Washington University, St. Louis, Missouri. Neely, S. T. (1993). \A model of cochlear mechanics with outer hair cell motility," J. Acoust. Soc. Am. 94, 137{146. Pujol, R., Lenoir, M., Ladrech, S., Tribillac, F., and Rebillard, G. (1991). \Correlation between the length of outer hair cells and the frequency coding of the cochlea," in: Auditory Physiology and Perception, edited by Y. Cazals, L. Demany and K. Horner (Plenum, New York) pp. in press. Ruggero, M. A., Rich, N. C., and Freyman, R. (1983). \Spontaneous and impulsively evoked otoacoustic emissions: Indicators of cochlear pathology?," Hear. Res. 10, 283{300. Santos-Sacchi, J. (1992). \On the frequency limit and phase of outer hair cell motility: Eects of the membrane lter," J. Neurosci. 12, 1906{1916. Sexl, T. (1930). \ Uber den von E. G. Richardson endeckten Annulareekt," Z. Phys. 61, 349{362. Shera, C. A., and Zweig, G. (1991). \Reection of retrograde waves within the 96
6 cochlea and at the stapes," J. Acoust. Soc. Am. 89, 1290{1305. Shera, C. A., and Zweig, G. (1995). \The origin of periodicity in the spectrum of evoked otoacoustic emissions," J. Acoust. Soc. Am. 98, 2018{2047. Spoendlin, H. (1978). \The aerent innervation of the cochlea," in: Evoked Electrical Activity in the Auditory Nervous System, edited by R. F. Naunton and C. Fernandez (Academic Press, New York and London) pp. 21{39. Steele, C. R., Baker, G., Tolomeo, J., and Zetes, D. (1993). \Electro-mechanical models of the outer hair cell," in: Biophysics of Hair Cell Sensory Systems, edited by H. Duifhuis, J. W. Horst, P. van Dijk and S. M. van Netten (World Scientic, Singapore) pp. 207{215. Steele, C. R. (1976). \Cochlear mechanics," in: Handbook of Sensory Physiology, Vol V/3, edited by W. D. Keidel and W. D. Ne (Springer{Verlag, Berlin) pp. 443{478. Strube, H. W. (1985). \A computationally ecient basilar-memebrane model," Acustica 58, 207{214. Strube, H. W. (1989). \Evoked otoacoustic emissions as cochlear Bragg reections," Hear. Res. 38, 35{46. Taber, L. A., and Steele, C. R. (1981). \Cochlear models including threedimensional uid and four modes of partition exibility," J. Acoust. Soc. Am. 70, 426{436. Talmadge, C. L., Long, G. R., Murphy, W. J., and Tubis, A. (1993). \New o-line method for detecting spontaneous otoacoustic emissions in human subjects," Hear. Res. 71, 170{182. Tsang, P. S. K., Schilstra, C., and van Netten, S. M. (1996). \Viscosity of the lateral line canal uid," in preparation. Tunstall, M. J., Ashmore, J. F., and Gale, J. E. (1994). \The eects of salicylate on properties of isolated outer hair cells from the guinea-pig cochlea," British Journal of Audiology 27, 332{333. Ulfendahl, M., Khanna, S. M., and Heneghan, C. (1995). \Shearing motion between the tectorial membrane and the reticular lamina in the isolated temporal bone preparation," Paper presented at the 18th Midwinter Research Meeting of the Association for Research in Otolaryngology, St. Petersburg Beach, Florida, Februari 5-9. van den Raadt, M. P. M. G., and Duifhuis, H. (1990). \A generalized Van der Pol oscillator model," in: The Mechanics and Biophysics of Hearing, edited by P. Dallos, C. D. Geisler, J. W. Matthews, M. A. Ruggero and C. R. Steele (Springer{Verlag, Berlin) pp. 227{234. van den Raadt, M. P. M. G., and Duifhuis, H. (1993). \Dierent boundary conditions in a one-dimensional time domain cochlea model," in: Biophysics of Hair Cell Sensory Systems, edited by H. Duifhuis, J. W. Horst, P. van Dijk and S. M. van Netten (World Scientic, Singapore) pp van Hengel, P. W. J., and Maat, A. (1993). \Periodicity in frequency spectra of click evoked and spontaneous OAE's; theory meets experiment," in: Biophysics of Hair Cell Sensory Systems, edited by H. Duifhuis, J. W. Horst, P. van Dijk and S. M. van Netten (World Scientic, Singapore) pp. 47{53. van Netten, S. M., and Kroese, A. B. A. (1987). \Laser interferometric measure- 97
7 ments on the dynamic behaviour of the cupula in the sh lateral line," Hearing Res. 29, 55{61. van Netten, S. M. (1987). Laser interferometric study of the mechanosensitivity of the sh lateral line. PhD thesis, University of Groningen, The Netherlands. van Netten, S. M. (1993). \A nonlinear model of cupular mechanics including the gating springs of the transduction channels of hair cells," in: Biophysics of hair cell sensory systems, edited by H. Duifhuis, J. W. Horst, P. van Dijk and S. M. van Netten (World Scientic, Singapore) pp. 391{397. Viergever, M. A., and Diependaal, R. J. (1983). \Simultaneous amplitude and phase match of cochlear model calculations and basilar membrane vibration data," in: Mechanics of Hearing, edited by E. de Boer and M. A. Viergever (Nijho, Den Haag) pp. 53{61. Viergever, M. A., and Diependaal, R. J. (1986). \Quantitative validation of cochlear models using the Liouville-Green approximation," Hear. Res. 21, 1{ 15. Viergever, M. A. (1978). \Basilar membrane motion in a spiral-shaped cochlea," J. Acoust. Soc. Am. 64, 1048{1053. Viergever, M. A. (1980). Mechanics of the inner ear. PhD thesis, Delft University of Technology, Netherlands. von Bekesy, G. (1960). Experiments in Hearing (McGraw-Hill, New York). Voss, S. E., and Allen, J. B. (1994). \Measurement of acoustic impedance and reectance in the human ear canal," J. Acoust. Soc. Am. 95, 372{384. Wever, E. G. (1970). Theory of Hearing (Dover, New York). Wit, H. P. (1990). \Spontaneous otoacoustic emission generators behave like coupled oscillators," in: The Mechanics and Biophysics of Hearing, edited by P. Dallos, C. D. Geisler, J. W. Matthews, M. A. Ruggero and C. R. Steele (Springer{ Verlag, Berlin) pp. 259{268. Zweig, G. (1991). \Finding the impedance of the organ of Corti," J. Acoust. Soc. Am. 89, 1229{1254. Zwicker, E. (1988). \Otoacoustic emissions and cochlear travelling waves," in: Cochlear Mechanisms, edited by J. P. Wilson and D. T. Kemp (Plenum, New York) pp. 359{366. Zwicker, E. (1990). \On the inuence of acoustical probe impedance on evoked otoacoustic emissions," Hear. Res. 47, 185{190. Zwislocki, J. (1950). \Theory of the acoustical action of the cochlea," J. Acoust. Soc. Am. 22, 778{
8 Publications van den Raadt, M. P. M. G., van Hengel, P. W. J., and Duifhuis, H. (1993). \Quantitative evaluation of spontaneous otoacoustic emissions in a one-dimensional macromechanical nonlinear cochlea model" to appear in: Advances in Otoacoustic Emissions { Volume I, edited by F. Grandori. van Hengel, P. W. J., and Maat, A. (1993). \Periodicity in frequency spectra of click evoked and spontaneous OAE's; theory meets experiment," in: Biophysics of Hair Cell Sensory Systems, edited by H. Duifhuis, J. W. Horst, P. van Dijk and S. M. van Netten (World Scientic, Singapore) pp. 47{53. van Hengel, P. W. J. (1995). \Spatial periodicity in the cochlea caused by interaction of spontaneous emissions" in: Advances in Hearing Research, edited by G. A. Manley, G. M. Klump, C. Koppl, H. Fastl and H. Oeckinghaus (World Scientic, Singapore) pp. 116{124. van Hengel, P. W. J., Duifhuis, H., and van den Raadt, M. P. M. G. (1996). \Spatial periodicity in the cochlea: The result of interaction of spontaneous emissions?" J. Acoust. Soc. Am. 99, 3566{3571. van Hengel, P. W. J., and Duifhuis, H. (1996). \Is there a second lter in the cochlea?" in preparation. Master s theses of students under my supervision: Meeuwissen, M. (1994). \Een numeriek model van de beweging van een cupula in het zijlijnkanaal". Hess, B. (1995). \A mathematical model of the inner ear of a bat". 99
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