Skip to main content

On ringing limits of the auditory periphery

Biological Cybernetics volume 63pages 433–442 (1990)Cite this article

Abstract

In classical hearing theory frequency and time have been treated as nearly independent acoustical dimensions. In this paper the interaction between temporal and spectral aspects is studied. An important determinant in this respect is the filtering of auditory stimuli in the cochlea. A view of auditory filtering that is balanced in frequency and time is obtained from the ‘reverse-correlation function’, abbreviated: revcor function. This function is derived from the response of an auditory-nerve fibre to a white-noise sound stimulus. It is a useful descriptor of peripheral filtering for a wide class of stimuli in which effects of nonlinear distortion are of minor importance. Measured revcor functions can be approximated by a standard mathematical function of which the parameters have a clear meaning. For these functions the spread in time and in frequency are uniquely related to one another. This relation is carried over to the case of cochlear filtering and applied to two important cases: stimulation by signals with small and with large amplitude variations. The results turn out to be markedly different in these two cases. In the final section the relevance of the results to various other fields of auditory research is discussed.

This is a preview of subscription content, access via your institution.

Access options

Buy single article

Instant access to the full article PDF.

43,34 €

Price includes VAT (Finland)
Tax calculation will be finalised during checkout.

References

  • Aertsen AMHJ, Johannesma PIM (1980) Spectro-temporal receptive fields of auditory neurons in the grassfrog. I. Characterization of tonal and natural stimuli. Biol Cybern 38: 223–234

    Google Scholar 

  • Allen JB (1983) Magnitude and phase-frequency response to single tones in the auditory nerve. J Acoust Soc Am 73: 2071–2092

    Google Scholar 

  • Anderson DJ, Rose JE, Hind JE and Brugge JF (1971) Temporal position of discharges in single auditory nerve fibers within the cycle of a sine-wave stimulus: frequency and intensity effects. J Acoust Soc Am 49: 1131–1138

    Google Scholar 

  • Arthus RM, Pfeiffer RR and Suga N (1971) Properties of ‘two-tone inhibition’ in primary auditory neurones. J Physiol (London) 212, 593–609

    Google Scholar 

  • de Boer E (1962) Note on the critical bandwidth. J Acoust Soc Am 34: 985–986

    Google Scholar 

  • de Boer E (1969) Encoding of frequency information in the discharge pattern of auditory nerve fibers. Intern Audiol 8: 547–556

    Google Scholar 

  • de Boer E (1975) Synthetic action potentials for the cat. J Acoust Soc Am 58: 1030–1045

    Google Scholar 

  • de Boer E (1978) Traveling waves and cochlear resonance. Scand Audiol [Suppl] 9: 17–33

    Google Scholar 

  • de Boer E (1983) No sharpening? A challenge for cochlear mechanics. J Acoust Soc Am 73: 567–573

    Google Scholar 

  • de Boer E (1989) On the nature of cochlear resonance. In: Wilson JP, Kemp DT (eds) Mechanics of hearing. Plenum Press, New York, pp 465–472

    Google Scholar 

  • de Boer E, de Jongh HR (1978) On cochlear encoding: Potentialities and limitations of the reverse-correlation technique. J Acoust Soc Am 63: 115–135

    Google Scholar 

  • de Boer E, Kuyper P (1968) Triggered correlation. IEEE Trans BME 15: 169–179

    Google Scholar 

  • Carney LH (1989) Temporal coding of resonances by low-frequency auditory nerve fibers: single-fiber responses and a population model. J Neurophysiol 60: 1653–1677

    Google Scholar 

  • Dallos P, Cheatham MA (1976) Compound action potential (AP) tuning curves. J Acoust Soc Am 59: 591–597

    Google Scholar 

  • Diependaal RJ, Viergever MA, de Boer E (1986) Are active elements necessary in the basilar membrane impedance? J Acoust Soc Am 80: 124–132

    Google Scholar 

  • Diependaal RJ, de Boer E, Viergever MA (1987) Cochlear power flux as an indicator of mechanical activity. J Acoust Soc Am 81: 184–186

    Google Scholar 

  • Duifhuis H (1973) Consequences of peripheral frequency selectivity for nonsimultaneous masking. J Acoust Soc Am 54: 1471–1488

    Google Scholar 

  • Eggermont JJ (1976) Electrocochleography. In: Keidel WD, Neff WD (eds) Handbook of sensory physiology, vol V/III. Springer, Berlin Heidelberg New York, pp 625–705

    Google Scholar 

  • Eggermont JJ, Johannesma PIM, Aertsen AMHJ (1984) Reverse correlation methods in auditory research. Rev Biophys 16: 341–414

    Google Scholar 

  • Evans EF (1977) Frequency selectivity at high signal levels of single units in cochlear nerve and nucleus. In: Evans EF, Wilson JP (eds) Phychophysics and physiology of hearing. Academic Press, London, pp 185–192

    Google Scholar 

  • Evans EF (1989) Cochlear filtering: A view seen through the temporal discharge patterns of single cochlear fibres. In: Wilson JP, Kemp DT (eds) Mechanics of hearing. Plenum Press, New York, pp 241–248

    Google Scholar 

  • Feldtkeller R, Zwicker E (1956) Das Ohr als Nachrichten-empfänger. Hirzel, Stuttgart

    Google Scholar 

  • Goblick TJ Jr, Pfeiffer RR (1969) Time-domain measurements of cochlear nonlinearities using combination click stimuli. J Acoust Soc Am 46: 924–938

    Google Scholar 

  • Goldstein JL (1967) Auditory nonlinearity. J Acoust Soc Am 41: 676–689

    Google Scholar 

  • Goldstein JL, Kiang NY-S (1968) Neural correlates of the aural combination tone 2f 1f 2. Proc IEEE 56: 981–992

    Google Scholar 

  • Goldstein JL, Baer T, Kiang NY-S (1971) A theoretical treatment of latency, group delay and tuning characteristics for auditory nerve responses to clicks and tones. In: Sachs MB (ed) Physiology of the auditory system. Natl Educat Consultants, Maryland, pp 133–141

    Google Scholar 

  • Hall JL (1974) Two-tone distortion products in a nonlinear model of the basilar membrane. J Acoust Soc Am 56: 1818–1828

    Google Scholar 

  • Johannesma PIM (1972) The pre-response stimulus ensemble of neurons in the cochlear nucleus. In: Cardozo BL (ed) Proceedings Symposium on Hearing Theory. IPO, Eindhoven, The Netherlands, pp 58–69

    Google Scholar 

  • Johannesma PIM, Aertsen A, Cranen B, van Erning L (1981) The phonochrome: A coherent spectro-temporal representation of sound. Hearing Res 5: 123–145

    Google Scholar 

  • Khanna SM, Leonard DGB (1982) Basilar membrane tuning in the cat cochlea. Science 215: 305–306

    Google Scholar 

  • Kiang NY-S, Watanabe T, Thomas EC, Clark LF (1965) Discharge patterns of single fibers in the cat's auditory nerve. MIT Press, Cambridge, Mass, USA

    Google Scholar 

  • Kim DO (1980) Cochlear mechanics: Implications of electrophysiological and acoustical observations. Hearing Res 2: 297–317

    Google Scholar 

  • Møller AR (1970) The use of correlation analysis in processing neuroelectronic data. In: Schade JP, Smith J (eds) Progress in brain research, vol 33. Elsevier, Amsterdam, pp 87–99

    Google Scholar 

  • Møller AR (1986) Systems identification using pseudorandom noise applied to a sensorineural system. Comp Math Appl 12A: 803–814

    Google Scholar 

  • Plomp R (1964) Rate of decay of auditory sensation. J Acoust Soc Am 36: 277–282

    Google Scholar 

  • Prijs VP (1980) Narrow-band analysis: a link between single-fibre and whole-nerve data. In: Vd Brink G, Bilsen FA (eds) Psychophysical, physiological and behavioural studies in hearing. Delft University Press, Delft, pp 166–170

    Google Scholar 

  • Robles L, Ruggero MA, Rich NC (1986) Mössbauer measurements of the mechanical response to single-tone and two-tone stimuli at the base of the chinchilla cochlea. In: Allen JB, Hall JL, Hubbard A, Neely ST, Tubis A (eds) Peripheral auditory mechanisms. Springer, Berlin Heidelberg New York, pp 121–128

    Google Scholar 

  • Russell IJ and Sellick PM (1978) Intracellular studies in the mammalian cochlea. J Physiol 284: 261–290

    Google Scholar 

  • Sachs MB, Abbas PJ (1974) Rate versus level functions for auditorynerve fibers in cats: Tone-burst stimuli. J Acoust Soc Am 56: 1835–1847

    Google Scholar 

  • Scharf B (1970) Critical bands. In: Tobias JV (ed) Foundations of modern auditory theory I. Academic Press, New York, pp 157–202

    Google Scholar 

  • Sellick PM, Patuzzi R and Johnstone BM (1982) Measurement of basilar membrane motion in the guinea pig using the Mössbauer technique. J Acoust Soc Am 72: 131–141

    Google Scholar 

  • Wijburg FA, de Boer E (1986) Time course of suppression. Hearing Res 23: 283–286

    Google Scholar 

Download references

Author information

Affiliations

  1. Academic Medical Centre, Rm D2-210, Meibergdreef 9, 1105, AZ Amsterdam, The Netherlands

    E. de Boer & C. Kruidenier

Authors
  1. E. de Boer
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. C. Kruidenier
    View author publications

    You can also search for this author in PubMed Google Scholar

Rights and permissions

Reprints and Permissions

About this article

Cite this article

de Boer, E., Kruidenier, C. On ringing limits of the auditory periphery. Biol. Cybern. 63, 433–442 (1990). https://doi.org/10.1007/BF00199575

Download citation

  • Received:

  • Accepted:

  • Issue Date:

  • DOI: https://doi.org/10.1007/BF00199575

Keywords

  • Mathematical Function
  • Large Amplitude
  • Final Section
  • Auditory Stimulus
  • Wide Class