Christophe Micheyl, PhD

Research Assistant Professor


email: cmicheyl@umn.edu
tel: 612 626 3291
fax: 612 626 3359

Auditory Perception and Cognition Group
Department of Psychology
University of Minnesota Twin Cities

N640 Elliott Hall,
75 East River Parkway,
Minneapolis, MN 55455


Recent

  • Dai H., Micheyl C. (2010) On the Choice of Adequate Randomization Ranges for Limiting the Use of Unwanted Cues in Same-Different, Dual-Pair, and Oddity Tasks. Attention, Perception & Psychophysics (send me an email for the PDF)
In this paper, we provide explanations, figures, tables, and example applications to help experimenters determine how wide a "roving" (or randomization) range they should use to limit performance based on an "unwanted" cue in same-different, oddity, or dual-pair experiments. Green's (1988) often-quoted formula (and the rule of thumb based on it, according to which the roving range should be about 4 times larger than the estimated unwanted-cue size) only applies to 2I-2AFC experiments; if applied to other paradigms, it can lead to serious over-estimation of the roving range needed to limit performance based on the "unwanted cue.
  • Micheyl, C., Oxenham, A.J. (2009) Pitch, harmonicity, and concurrent sound segregation: Psychoacoustical and neurophysiological findings. Hearing Research, Annual Reviews 2010 PDF
In this paper, we review recent (and not-so-recent) findings concerning the perception and neural coding of concurrent harmonic sounds (including double vowels and mistuned harmonics).
  • Dai H., Micheyl C. (2010) Psychophysical reverse correlation and multiple alternatives. Journal of Experimental Psychology: Human Perception and Performance (in press) PDF
Psychophysical "reverse correlation" methods (e.g., Ahumada's "classification-image" technique )provide a unique tool to explore perceptual templates and individual decision strategies. In this paper, we show how, and under what conditions, the "correlational" technique can be used to measure perceptual templates/decision weights in experiments involving more than just two alternatives.
  • Micheyl C., Hunter C., Oxenham A.J. (2010) Auditory stream segregation and the perception of across-frequency synchrony. Journal of Experimental Psychology: Human Perception and Performance (in press) PDF
In this paper, we demonstrate that the detection of synchrony, which has traditionally been regarded as a powerful simultaneous-grouping cue, can be severly disrupted by sequential grouping (i.e., auditory streaming).
  • Micheyl C., Dai H. (2009) Likelihood Ratio, optimal decision rules, and relationship between Pc and d′ in the dual-pair change-direction-identification paradigm. Attention, Perception & Psychophysics 71, 1426-1433. PDF
In this paper, we analyze the ideal (i.e., maximum-likelihood) decision strategy of an (equal-variance Gaussian) observer in the dual-pair stimulus-comparison task, which has been used in various recent studies of auditory perception (e.g., Semal and Demany, 2006).
  • Oxenham A.J., Micheyl C., Keebler M. V. (2009) Can temporal fine structure represent the fundamental frequency of unresolved harmonics? Journal of the Acoustical Society of America 125, 2189-2199 PDF
In this paper, we show that recent results by Moore et al. (2006) JASA 119, which were originally interpreted as evidence for Schouten's (1940) idea that residue-pitch perception relies on temporal fine-structure peaks under envelope maxima, were probably contaminated by distortion-product cues.
  • Elhilali M., Ma L., Micheyl C., Oxenham A.J., Shamma S.A. (2009) Temporal Coherence in the Perceptual Organization and Cortical Representation of Auditory Scenes. Neuron 61, 317-329 PDF
In this paper, we combine psychophysics in humans with single-unit recordings in ferrets to show that rate-based population responses in primary auditory cortex are insufficient to account for the perceptual organization of sounds into streams. We also describe a neurophysiologically inspired computational model of auditory streaming that makes use of temporal coherence (correlation) across cortical channels.
  • Micheyl C., Kaernbach C., Demany L. An evaluation of psychophysical models of auditory change detection. Psychological Review 115, 1069-1083 PDF
In this paper, we demonstrate that neither the popular equal-variance Gaussian SDT model, nor the intuitive "high-threshold" model, provide a satisfactory account of empirical data on the relationship between listeners' ability to detect changes in sound (intensity, frequency, or modulation rate) and the identification of the direction (up or down) of these changes. In contrast, a neurophysiologically inspired "Poisson" model (which assumes discrete rather than continuous auditory sensations) does.
  • Pressnitzer D., Sayles M., Micheyl C., Winter M. Perceptual organization of sound begins in the auditory periphery.(2008)  Current Biology 18, 1124-1228 PDF (Preview by Jan Schnupp PDF)
In this paper, we demonstrate that neural responses to tone sequences in the cochlear nucleus (the first obligatory station in the central auditory system) decrease ("adapt") over several seconds , and that the characteristics of this adaptation are quantitatively consistent with the perceptual build-up of stream segregation in human listeners.
  • Gutschalk A., Micheyl C., Oxenham A.J. (2008) Neural correlates of perceptual awareness using informational masking. PLoS Biology 10, e138 PDF 
In this paper, we show that neural responses in secondary (but not primary) auditory cortex covary with the conscious detection of target tones in an "informational" (randomly varying) masker.
  • Bee M., Micheyl C. (2008) The “cocktail-party problem”: What is it? How can it be solved? And why should animal behaviorists study it? Journal of Comparative Psychology 122 PDF
In this paper, we review behavioral and psychophysical findings concerning auditory-scene-analysis in humans and other species.
  • Micheyl C., McDermott, J.H., Oxenham, A.J. (2008) Sensory noise explains auditory frequency discrimination learning induced by training with identical stimuli. Attention, Perception & Psychophysics 71, 5-7 PDF
In this paper, we provide a simple explanation for a seemingly puzzling finding by Amitay et al. (2006, Nature Neuroscience), who  showed that thresholds in an auditory frequency-discrimination task were improved by practice even if the tones presented during the practice phase do not differ in frequency.

By Topic

Signal Detection Theory
  • Dai H., Micheyl C. On the Choice of Adequate Randomization Ranges for Limiting the Use of Unwanted Cues in Same-Different, Dual-Pair, and Oddity Tasks. Attention, Perception & Psychophysics (upcoming)
  • Micheyl C., Dai H. Likelihood Ratio, Optimal decision rules, and relationship between Pc and d′ in the dual-pair change-direction-identification paradigm. Attention, Perception & Psychophysics (in press) PDF
  • Dai H., Micheyl C. Psychophysical Reverse Correlation and Multiple Alternatives. Journal of Experimental Psychology: Human Perception and Performance (in press) PDF
  • Micheyl C., McDermott, J.H., Oxenham, A.J. (2008) Sensory noise explains auditory frequency discrimination learning induced by training with identical stimuli. Attention, Perception & Psychophysics 71, 5-7 PDF
  • Micheyl C., Kaernbach C., Demany L. An evaluation of psychophysical models of auditory change detection. Psychological Review (in press) PDF
  • Micheyl C., Dai, H. A General Area Theorem for the Same-Different (2IAX) Paradigm. Perception & Psychophysics 70, 761-764 PDF
  • Micheyl C., Messing D.P. (2006) Likelihood ratio, optimal decision rules, and correct response probabilities in a signal-detection theoretic, equal-variance Gaussian model of the observer in the 4IAX paradigm. Perception & Psychophysics 68, 725-735. PDF
Brain Basis of Auditory Perception
  • Micheyl, C., Oxenham, A.J. (2009) Pitch, harmonicity, and concurrent sound segregation: Psychoacoustical and neurophysiological findings. Hearing Research, Annual Reviews 2010 PDF
  • Elhilali M., Ma L., Micheyl C., Oxenham A.J., Shamma S.A. (2009) Temporal Coherence in the Perceptual Organization and Cortical Representation of Auditory Scenes. Neuron 61, 317-329 PDF
  • Pressnitzer D., Sayles M, Micheyl C., Winter M. Perceptual organization of sound begins in the auditory periphery. Current Biology 18, 1124-1228 PDF (Preview by Jan Schnupp PDF)
  • Gutschalk A., Micheyl C., Oxenham A.J. Neural correlates of perceptual awareness using informational masking. PLoS Biology 10, e138 PDF 
  • Gutschalk A., Oxenham A.J., Micheyl C., Wilson E.C. Melcher, J.R.M. (2007) Human cortical activity during streaming without spectral cues suggests a general neural substrate for auditory stream segregation, Journal of Neuroscience 28, 13074-13081. PDF
  • Wilson E.C., Melcher J.R., Micheyl C., Gutschalk A., Oxenham A.J. (2007) Cortical fMRI activation to sequences of tones alternating in frequency: Relationship to perceived rate and streaming. Journal of Neurophysiology 97, 2230-2238. PDF
  • Micheyl C., Carlyon R.P., Gutschalk, A., Melcher J.R.M., Oxenham A.J., Rauschecker J.P., Tian B., Wilson E.C. (2007) The role of auditory cortex in the formation of auditory streams. Hearing Research 229, 1161-131. PDF
  • Gutschalk A., Micheyl C., Melcher, J.R., Rupp A., Scherg M., Oxenham A.J. (2005).Neuromagnetic correlates of streaming in human auditory cortex. Journal of Neuroscience 25, 5382-5388. PDF
  • Micheyl C., Tian B., Carlyon R.P., Rauschecker J.P. (2005) Perceptual organization of sound sequences in the auditory cortex of awake macaques. Neuron 6, 139-148 PDF (PDF of Preview by DeWeese & Zador)
  • Kanwal J., Medvedev G., Micheyl C. (2003) Neurodynamics for auditory stream segregation: tracking sounds in the mustached bat’s natural environment. Network: Computation in Neural Systems 14, 413-435. PDF
  • Micheyl C., Pulvermuller F., Carlyon R.P., Shtyrov Y., Hauk O., and Dodson T. (2003) The neurophysiological basis of the auditory continuity illusion. Journal of Cognitive Neuroscience 15, 747-758. PDF
Pitch Perception
  • Micheyl, C., Oxenham, A.J. (2009) Pitch, harmonicity, and concurrent sound segregation: Psychoacoustical and neurophysiological findings. Hearing Research, Annual Reviews 2010 PDF
  • Oxenham A.J., Micheyl C., Keebler M. V. (2009) Can temporal fine structure represent the fundamental frequency of unresolved harmonics? Journal of the Acoustical Society of America 125, 2189-2199 PDF 
  • Micheyl C., Oxenham A.J. (2007) Across-frequency pitch discrimination interference between complex tones containing resolved harmonics. Journal of the Acoustical Society of America 121, 1621-1631. PDF
  • Micheyl C., Bernstein J.G.W., Oxenham A.J. (2006) Detection and F0 discrimination of concurrent harmonic complex tones. Journal of the Acoustical Society of America 120, 1493-1505. PDF
  • Micheyl C., Oxenham A.J. (2005) Comparing F0 discrimination in sequential and simultaneous conditions. Journal of the acoustical Society of America 188, 41-44. PDF
    Micheyl C., Oxenham A. J. (2004) Sequential F0 comparisons between resolved and unresolved harmonics: no evidence for across-pitch-mechanisms translation noise. Journal of the acoustical Society of America 116, 3038-3050. PDF
  • Carlyon R. P., Moore B. C. J., Micheyl C. (2000) The effect of modulation rate on the detection of frequency modulation and mistuning of complex tones. Journal of the Acoustical Society of America 108, 304-315. PDF
  • Gockel H., Carlyon R.P., Micheyl C. (1999) Context dependence of fundamental frequency discrimination: Lateralized temporal fringes. Journal of the Acoustical Society of America 106, 3553-3563. PDF
  • Micheyl C., Carlyon R.P. (1998) Effects of temporal fringes on fundamental frequency discrimination. Journal of the Acoustical Society of America 104, 3006-3018. PDF
  • Micheyl C., Moore B.C.J., Carlyon R. P. (1998) The role of excitation-pattern and temporal cues in the frequency and modulation-rate discrimination of amplitudemodulated tones. Journal of the Acoustical Society of America 104, 1039-1050. PDF
Auditory Scene Analysis (Auditory Streaming, Concurrent-Sound Segregation)
  • Micheyl, C., Oxenham, A.J. (2009) Pitch, harmonicity, and concurrent sound segregation: Psychoacoustical and neurophysiological findings. Hearing Research, Annual Reviews 2010 PDF
  • Micheyl C., Hunter C., Oxenham A.J. Auditory stream segregation and the perception of across-frequency synchrony. Journal of Experimental Psychology: Human Perception and Performance (accepted for publication) PDF
  • Elhilali M., Ma L., Micheyl C., Oxenham A.J., Shamma S.A. (2009) Temporal Coherence in the Perceptual Organization and Cortical Representation of Auditory Scenes. Neuron 61, 317-329 PDF
  • Bee M., Micheyl C. (2008) The “cocktail-party problem”: What is it? How can it be solved? And why should animal behaviorists study it? Journal of Comparative Psychology 122 PDF
  • Pressnitzer D., Sayles M, Micheyl C., Winter M. Perceptual organization of sound begins in the auditory periphery. Current Biology 18, 1124-1228 PDF (Preview by Jan Schnupp PDF)
  • Gutschalk A., Micheyl C., Oxenham A.J. Neural correlates of perceptual awareness using informational masking. PLoS Biology 10, e138 PDF 
  • Gutschalk A., Oxenham A.J., Micheyl C., Wilson E.C. Melcher, J.R.M. (2007) Human cortical activity during streaming without spectral cues suggests a general neural substrate for auditory stream segregation, Journal of Neuroscience 28, 13074-13081. PDF
  • Wilson E.C., Melcher J.R., Micheyl C., Gutschalk A., Oxenham A.J. (2007) Cortical fMRI activation to sequences of tones alternating in frequency: Relationship to perceived rate and streaming. Journal of Neurophysiology 97, 2230-2238. PDF
  • Micheyl C., Carlyon R.P., Gutschalk, A., Melcher J.R.M., Oxenham A.J., Rauschecker J.P., Tian B., Wilson E.C. (2007) The role of auditory cortex in the formation of auditory streams. Hearing Research 229, 1161-131. PDF
  • Micheyl C., Bernstein J.G.W., Oxenham A.J. (2006) Detection and F0 discrimination of concurrent harmonic complex tones. Journal of the Acoustical Society of America 120, 1493-1505. PDF
  • Gutschalk A., Micheyl C., Melcher, J.R., Rupp A., Scherg M., Oxenham A.J. (2005).Neuromagnetic correlates of streaming in human auditory cortex. Journal of Neuroscience 25, 5382-5388. PDF
  • Micheyl C., Tian B., Carlyon R.P., Rauschecker J.P. (2005) Perceptual organization of sound sequences in the auditory cortex of awake macaques. Neuron 6, 139-148 PDF (PDF of Preview by DeWeese & Zador)
  • Kanwal J., Medvedev G., Micheyl C. (2003) Neurodynamics for auditory stream segregation: tracking sounds in the mustached bat’s natural environment. Network: Computation in Neural Systems 14, 413-435. PDF
  • Grimault N., Bacon S.P., Micheyl C. (2002) Auditory stream segregation on the basis of amplitude modulation rate. Journal of the Acoustical Society of America 111, 1340-1348. PDF
  • Grimault N., Micheyl C., Carlyon R.P., Collet L. (2001) Perceptual auditory stream segregation of sequences of complex sounds in subjects with normal and impaired hearing. British Journal of Audiology 35, 173-182
  • Grimault N., Micheyl C., Carlyon R. P., Arthaud P., Collet L. (2000) Influence of peripheral harmonic resolvability on the perceptual segregation of complex tones differing in fundamental frequency. Journal of the Acoustical Society of America 108, 263-271. PDF
  • Carlyon R. P., Moore B. C. J., Micheyl C. (2000) The effect of modulation rate on the detection of frequency modulation and mistuning of complex tones. Journal of the Acoustical Society of America 108, 304-315. PDF
Perceptual Learning
  • Micheyl C., McDermott, J.H., Oxenham, A.J. (2008) Sensory noise explains auditory frequency discrimination learning induced by training with identical stimuli. Attention, Perception & Psychophysics 71, 5-7 PDF
  • Micheyl C., Delhommeau K., Perrot X., Oxenham A.J. (2006) Influence of musical learning and psychoacoustical training on pitch discrimination. Hearing Research 219, 36-47. PDF
  • Delhommeau K., Micheyl C., Jouvent R. (2005) Generalization of frequency discrimination learning across frequencies and ears: implications for underlying neural mechanisms in humans. Journal of the Association for Research in Otolaryngology 6, 171-179. PDF
  • Grimault, N., Micheyl C., Carlyon R. P., Bacon S.P., Collet L. (2003) Learning in discrimination of frequency or modulation rate: generalization to fundamental frequency discrimination. Hearing Research, 184, 41-50. PDF
  • Grimault N., Micheyl C., Carlyon R. P., Arthaud P., Collet L. (2002) Evidence for two pitch encoding mechanisms using a selective auditory training paradigm. Perception & Psychophysics 64, 189-97. PDF
  • Delhommeau K., Micheyl C., Jouvent R., Collet L. (2002) Transfer of frequency discrimination learning across durations and ears in auditory frequency discrimination. Perception & Psychophysics 64, 426-36. PDF
Perceptual Correlates of Central Auditory Plasticity
  • Thai-Van H., Micheyl C., Norena A., Veuillet E., Gabriel D., Collet L. (2007) Enhanced frequency discrimination thresholds near the audiogram edge in hearingimpaired individuals: a correlate of central neural plasticity induced by peripheral damages? Hearing Research 223, 14-22. PDF
  • Norena A., Micheyl C., Chery-Croze S., Collet L. (2002) Psychoacoustic characterization of the tinnitus spectrum: implications for the underlying mechanisms of tinnitus. Audiology & NeuroOtology 7, 358-69. PDF
  • Norena A., Micheyl C., Durrant J.D., Chery-Croze S., Collet L. (2002) Perceptual correlates of neural plasticity related to spontaneous otoacoustic emissions? Hearing Research 71, 66-. PDF
  • Norena A., Micheyl C., Durrant J.D., Collet L. (2002) Loudness changes associated with the perception of an auditory after-image. International Journal of Audiology 41, 202-207. 
  • Thai Van H., Micheyl C., Collet L., Moore B.C.J. (2003) Enhanced frequency discrimination near the hearing loss cutoff: a consequence of central auditory plasticity induced by cochlear damage? Brain 126, 2235-2245. PDF
  • Thai Van H., Micheyl C., Norena A., Collet L. (2002) Local improvement in auditory frequency discrimination is associated with hearing loss slope in cochlear-damaged subjects. Brain 125, 524-537. PDF
Auditory Illusions, After-effects, Tinnitus
  • Gutschalk A., Micheyl C., Oxenham A.J. (2008) The pulse train auditory after-effect and the perception of rapid amplitude modulations. Journal of the Acoustical Society of America 123, 935-945. PDF
  • Thai-Van H., Micheyl C., Norena A., Veuillet E., Gabriel D., Collet L. (2007) Enhanced frequency discrimination thresholds near the audiogram edge in hearingimpaired individuals: a correlate of central neural plasticity induced by peripheral damages? Hearing Research 223, 14-22. PDF
  • Gilbert G., Micheyl C. (2005). Influence of competing multi-talker babble on frequency-importance functions for speech measured using a correlational approach. Acustica united with Acta Acustica 91, 145-154.
  • Carlyon R. P., Micheyl C., Deeks J. D., Moore B. C. J. (2004). Auditory processing of real and illusory changes in FM phase. Journal of the acoustical Society of America 116, 3629-3639. PDF
  • Micheyl C., Pulvermuller F., Carlyon R.P., Shtyrov Y., Hauk O., and Dodson T. (2003) The neurophysiological basis of the auditory continuity illusion. Journal of Cognitive Neuroscience 15, 747-758. PDF
  • Norena A., Micheyl C., Chéry-Croze S. (2000) An auditory negative after-image as a human model of tinnitus. Hearing Research 149, 24-32. PDF
Auditory Perception in Hearing Impaired Listeners, Cochlear Implants
  • Garnier S., Micheyl C., Arthaud P., Collet L. (2001) Effect of frequency content on categorical loudness normalization. Scandinavian Audiology 29, 253-9.
  • Micheyl C., Arthaud P, Reinhart C., Collet L. (2000) Informational masking in normal hearing and hearing-impaired listeners. Acta Otolaryngologica (Stockholm) 120, 242-246.
  • Garnier S., Micheyl C., Arthaud P., Berger-Vachon C., Collet L. (1999) Temporal loudness integration and spectral loudness summation in normal-hearing and hearing-impaired listeners. Acta Otolaryngologica (Stockholm) 119, 154-157.
  • Gallégo S., Garnier S., Micheyl C., Tuy E., Morgon A., Collet L. (1999) Loudness growth functions and EABR characteristics in Digisonic cochlear implantees. Acta Otolaryngologica (Stockholm) 119, 234-238.
  • Garnier S., Micheyl C., Berger-Vachon C., Collet L. (1999). Categorical loudness scaling in normal-hearing and hearing-impaired listeners. I: Effect of signal duration. Audiology 38, 196-201
  • Gallégo S., Frachet B., Micheyl C., Truy E., Collet L. (1998) Cochlear implant performance and electrically-evoked auditory brainstem response characteristics Electroencephalography and Clinical Neurophysiology 108, 521-525.
  • Gallégo S., Micheyl C. (1998) Intensity discrimination and auditory brainstem responses in cochlear-implant and normal-hearing listeners. Behavioral Neuroscience 112, 793-799
  • Lorenzi C., Micheyl C., Berthommier F., Portalier S. (1997) Modulation masking in listeners with sensorineural hearing loss. Journal of Speech Language and Hearing Research 40, 200-207
  • Gallégo S., Micheyl C., Berger-Vachon C., Truy E., Morgon A., Collet L. (1996) Ipsilateral ABR with cochlear implant. Acta Otolaryngologica (Stockholm) 116, 228-233.
Olivocochlear System, Otoacoustic Emissions
  • Morand-Villeneuve N., Garnier S., Grimault N., Veuillet E., Collet L., Micheyl C. (2002) Medial olivocochlear bundle activation and perceived auditory intensity in humans. Physiology & Behavior 77, 311-20.
  • Maison S., Durrant J., Gallineau C., Micheyl C., Collet L. (2001) Delay and temporal integration in medial olivocochlear bundle activation in humans. Ear & Hearing 22, 65-74.
  • Maison S., Micheyl C., Collet L. (2000) Influence of focused auditory attention on cochlear activity in humans. Psychophysiology 38, 35-40.
  • Maison S., Micheyl C., Andéol G., Gallégo S., Collet L. (2000) Activation of medial olivocochlear efferent system in humans : influence of stimulus bandwidth. Hearing Research 140, 111-125.
  • Maison S., Micheyl C., Collet L. (1999) Sinusoidal amplitude modulation alters contralateral noise suppression of evoked otoacoustic emissions in humans. Neuroscience 91, 133-138.
  • Perrot X., Micheyl C., Khalfa S., Collet L. (1999) Stronger bilateral efferent influences on cochlear biomechanical activity in musicians than in non-musicians. Neuroscience Letters 262, 167-170.
  • Micheyl C., Maison S., Carlyon R.P., Andéol G., Collet L. (1999) Contralateral suppression of transiently-evoked otoacoustic emissions by harmonic complex tones in humans. Journal of the Acoustical Society of America 105, 293-305.
  • Maison S., Micheyl C., Collet L. (1999) The medial olivocochlear efferent system in humans: structure and function. Scandinavian Audiology 28 Suppl. 51, 77-84
  • Maison S, Micheyl C., Collet L. (1998) Contralateral frequency-modulated tones suppress transient-evoked otoacoustic emissions in humans. Hearing Research 117, 114-118
  • Khalfa S, Micheyl C., Veuillet E., Collet L. (1998) Peripheral auditory lateralization assessment using EOAEs. Hearing Research 121, 29-34
  • Giraud A.L., Garnier S., Micheyl C., Lina G., Chays A., Chéry-Croze S. (1997) Auditory efferents involved in speech-in-noise intelligibility. NeuroReport 8, 1779- 1783
  • Khalfa S., Morlet T., Micheyl C., Morgon A., Collet L. (1997) Evidence of peripheral hearing asymmetry in humans: Clinical implications. Acta Otolaryngologica (Stockholm) 117, 192-196
  • Micheyl C., Perrot X., Collet L. (1997) Relationship between auditory intensity discrimination in noise and olivocochlear efferent system activity in humans. Behavioral Neuroscience 111, 801-807
  • Micheyl C., Khalfa S., Perrot X, Collet L. (1997) Differences in cochlear efferent activity between musicians and nonmusicians. NeuroReport 8, 1047-1050
  • Méric C., Micheyl C., Collet L. (1996) Attention and evoked otoacoustic emissions: attempts at characterization of intersubject variation. Physiology & Behavior 59, 1-9
  • Micheyl C., Collet L. (1996) Involvement of the olivocochlear bundle in the detection of tones in noise. Journal of the Acoustical Society of America 99, 1604-1610
  • Maison S., Micheyl C., Collet L. (1997) Medial olivocochlear efferent system in humans studied with amplitude-modulated tones. Journal of Neurophysiology 77, 1759-1768
  • Maison S., Micheyl C., Chays A., Collet L. (1997) Medial olivocochlear efferent system stabilizes active cochlear micromechanical properties in humans. Hearing Research 113, 89-98
  • Micheyl C., Morlet T., Giraud A.L., Collet L., Morgon A. (1995) Contralateral suppression of evoked otoacoustic emissions and detection of a multi-tone complex in noise. Acta Otolaryngologica (Stockholm) 115, 178-182
  • Micheyl C., Carbonnel O., Collet L. (1995) Medial olivocochlear system and loudness adaptation : differences between musicians and non-musicians. Brain & Cognition 29, 127-136.
  • Lorenzi C., Micheyl C., Berthommier F. (1995) Neuronal correlates of perceptual amplitude-modulation detection. Hearing Research 90, 219-227
  • Collet L., Veuillet E., Moulin A., Morlet T., Giraud A.L., Micheyl C., Chéry-Croze S. (1994) Contralateral auditory stimulation and otoacoustic emissions: a review of basic data in humans. British Journal of Audiology 28, 213-218
  • Micheyl C., Collet L. (1994) Interrelations between psychoacoustical tuning curves and spontaneous and evoked otoacoustic emissions. Scandinavian Audiology 23, 171-178
Misc
  • Raphel C., Cian C., Barraud P.A., Micheyl C. (2001) Effects of supine body position and low radial accelerations on the visually perceived apparent zenith. Perception & Psychophysics 63:36-46.
  • Morand-Villeneuve N., Micheyl C., Gagnieu M.C., Lemoine P., Sebert P., Collet L., Veuillet E. (2003) Influence of benzodiazepines on auditory perception. Neuropsychopharmacology 28, 778-786.


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