Citation Relationships

Legends: Link to a Model Reference cited by multiple papers

Zilany MS, Bruce IC (2006) Modeling auditory-nerve responses for high sound pressure levels in the normal and impaired auditory periphery. J Acoust Soc Am 120:1446-66 [PubMed]

   Cat auditory nerve model (Zilany and Bruce 2006, 2007)

References and models cited by this paper

References and models that cite this paper

Anderson DJ, Rose JE, Hind JE, 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:Suppl 2:1131+ [PubMed]
Bondy J, Becker S, Bruce I, Trainor L, Haykin S (2004) A novel signal-processing strategy for hearing-aid design: Neurocompensation Signal Processing 84:1239-1253
Brown GJ, Cooke MP (1994) Computational auditory scene analysis Computer Speech And Language 8:297-336
Bruce IC (2004) Physiological assessment of contrast-enhancing frequency shaping and multiband compression in hearing aids. Physiol Meas 25:945-56 [PubMed]
Bruce IC, Sachs MB, Young ED (2003) An auditory-periphery model of the effects of acoustic trauma on auditory nerve responses. J Acoust Soc Am 113:369-88 [PubMed]
Cai Y (1995) Temporal responses of the auditory-nerve fibers to singletone and two-tone stimuli: Experimental and modeling studies PhD Thesis University of Wisconsin
Cai Y, Geisler CD (1996) Temporal patterns of the responses of auditory-nerve fibers to low-frequency tones. Hear Res 96:83-93 [PubMed]
Carney LH (1993) A model for the responses of low-frequency auditory-nerve fibers in cat. J Acoust Soc Am 93:401-17 [PubMed]
Carney LH (1994) Spatiotemporal encoding of sound level: models for normal encoding and recruitment of loudness. Hear Res 76:31-44 [PubMed]
Carney LH, McDuffy MJ, Shekhter I (1999) Frequency glides in the impulse responses of auditory-nerve fibers. J Acoust Soc Am 105:2384-91 [PubMed]
Carney LH, Yin TC (1988) Temporal coding of resonances by low-frequency auditory nerve fibers: single-fiber responses and a population model. J Neurophysiol 60:1653-77 [Journal] [PubMed]
Cheatham MA, Dallos P (1989) Two-tone suppression in inner hair cell responses. Hear Res 40:187-96 [PubMed]
Cheatham MA, Dallos P (1998) The level dependence of response phase: observations from cochlear hair cells. J Acoust Soc Am 104:356-69 [PubMed]
Cooper NP, Rhode WS (1992) Basilar membrane mechanics in the hook region of cat and guinea-pig cochleae: sharp tuning and nonlinearity in the absence of baseline position shifts. Hear Res 63:163-90 [PubMed]
Cooper NP, Rhode WS (1997) Mechanical responses to two-tone distortion products in the apical and basal turns of the mammalian cochlea. J Neurophysiol 78:261-70 [Journal] [PubMed]
Dallos P (1985) Response characteristics of mammalian cochlear hair cells. J Neurosci 5:1591-608 [PubMed]
Dallos P (1986) Neurobiology of cochlear inner and outer hair cells: intracellular recordings. Hear Res 22:185-98 [PubMed]
de Boer E, de Jongh HR (1978) On cochlear encoding: potentialities and limitations of the reverse-correlation technique. J Acoust Soc Am 63:115-35 [PubMed]
de Boer E, Nuttall AL (1997) The mechanical waveform of the basilar membrane. I. Frequency modulations ("glides") in impulse responses and cross-correlation functions. J Acoust Soc Am 101:3583-92 [PubMed]
de Boer E, Viergever MA (1982) Validity of the Liouville--Green (or WKB) method for cochlear mechanics. Hear Res 8:131-55 [PubMed]
de Boer R, Kuyper P (1968) Triggered correlation. IEEE Trans Biomed Eng 15:169-79 [PubMed]
Delgutte B (1990) Two-tone rate suppression in auditory-nerve fibers: dependence on suppressor frequency and level. Hear Res 49:225-46 [PubMed]
Deng L, Geisler CD (1987) A composite auditory model for processing speech sounds. J Acoust Soc Am 82:2001-12 [PubMed]
Evans EF (1981) The dynamic range problem: Place and time coding at the level of the cochlear nerve and nucleus Neuronal Mechanisms and Hearing, Syka J:Atkins LM, ed. pp.69
Geisler CD, Rhode WS (1982) The phases of basilar-membrane vibrations. J Acoust Soc Am 71:1201-3 [PubMed]
Ghitza O (1988) Temporal non-place information in the auditory-nerve firing patterns as a front-end for speech recognition in a noisy environment. J Phonetics 16:109-123
Gifford ML, Guinan JJ (1983) Effects of crossed-olivocochlear-bundle stimulation on cat auditory nerve fiber responses to tones. J Acoust Soc Am 74:115-23 [PubMed]
Giguère C, Woodland PC (1994) A computational model of the auditory periphery for speech and hearing research. I. Ascending path. J Acoust Soc Am 95:331-42 [PubMed]
Goblick TJ, Pfeiffer RR (1969) Time-domain measurements of cochlear nonlinearities using combination click stimuli. J Acoust Soc Am 46:924-38 [PubMed]
Goldstein JL (1990) Modeling rapid waveform compression on the basilar membrane as multiple-bandpass-nonlinearity filtering. Hear Res 49:39-60 [PubMed]
Goldstein JL (1995) Relations among compression, suppression, and combination tones in mechanical responses of the basilar membrane: data and MBPNL model. Hear Res 89:52-68 [PubMed]
Heinz MG () private communication
Heinz MG, Young ED (2004) Response growth with sound level in auditory-nerve fibers after noise-induced hearing loss. J Neurophysiol 91:784-95 [Journal] [PubMed]
Hewitt MJ, Meddis R (1993) Regularity of cochlear nucleus stellate cells: a computational modeling study. J Acoust Soc Am 93:3390-9 [PubMed]
Holley MC (1996) Outer hair cell motility. The Cochlea., Dallos P,Popper AN, Fay RR, ed. pp.386
Johnson DH (1980) The relationship between spike rate and synchrony in responses of auditory-nerve fibers to single tones. J Acoust Soc Am 68:1115-22 [PubMed]
Kates JM (1991) A time-domain digital cochlear model IEEE Trans Signal Processing 39:2573-2592
Kates JM (1995) Two-tone suppression in a cochlear model IEEE Trans Speech Audio Process 3:396-406
Kiang NY (1990) Curious oddments of auditory-nerve studies. Hear Res 49:1-16 [PubMed]
Kiang NY, Liberman MC, Levine RA (2006) Auditory-nerve activity in cats exposed to ototoxic drugs and high-intensity sounds. Ann Otol Rhinol Laryngol 85:752-68
Kiang NY, Liberman MC, Sewell WF, Guinan JJ (1986) Single unit clues to cochlear mechanisms. Hear Res 22:171-82 [PubMed]
Kiang NYS (1984) Peripheral neural processing of auditory information Handbook of Physiology, Section 1: The Nervous System, Brookhart JM:Mountcastle VB, ed. pp.639
Kiang NYS, Baer T, Marr EM, Demont D (1969) Discharge rates of single auditory-nerve fibers as a function of tone level J Acoust Soc Am 46:106
Kiang NYS, Watanabe T, Thomas C, Clark LF (1965) Discharge Patterns Of Single Fibers In The Cats Auditory Nerve
Liberman MC (1978) Auditory-nerve response from cats raised in a low-noise chamber. J Acoust Soc Am 63:442-55 [PubMed]
Liberman MC (1982) The cochlear frequency map for the cat: labeling auditory-nerve fibers of known characteristic frequency. J Acoust Soc Am 72:1441-9 [PubMed]
Liberman MC (1984) Single-neuron labeling and chronic cochlear pathology. I. Threshold shift and characteristic-frequency shift. Hear Res 16:33-41 [PubMed]
Liberman MC, Dodds LW (1984) Single-neuron labeling and chronic cochlear pathology. III. Stereocilia damage and alterations of threshold tuning curves. Hear Res 16:55-74 [PubMed]
Liberman MC, Kiang NY (1984) Single-neuron labeling and chronic cochlear pathology. IV. Stereocilia damage and alterations in rate- and phase-level functions. Hear Res 16:75-90 [PubMed]
Liberman MC, Mulroy MJ (1982) Acute and chronic effects of acoustic trauma: Cochlear pathology and auditory nerve pathophysiology New Perspectives on Noise-Induced Hearing Loss, Hamernik RP:Henderson D:Salvi R, ed. pp.105
Lin T (1994) Quantitative modeling of nonlinear auditory-nerve responses as two-factor interactions PhD Thesis Washington University
Lin T, Goldstein JL (1995) Quantifying 2-factor phase relations in non-linear responses from low characteristic-frequency auditory-nerve fibers. Hear Res 90:126-38 [PubMed]
Lin T, Guinan JJ (2000) Auditory-nerve-fiber responses to high-level clicks: interference patterns indicate that excitation is due to the combination of multiple drives. J Acoust Soc Am 107:2615-30 [PubMed]
Lin T, Guinan JJ (2004) Time-frequency analysis of auditory-nerve-fiber and basilar-membrane click responses reveal glide irregularities and non-characteristic-frequency skirts. J Acoust Soc Am 116:405-16 [PubMed]
Lopez-Poveda EA (2005) Spectral processing by the peripheral auditory system: facts and models. Int Rev Neurobiol 70:7-48 [Journal] [PubMed]
Matthews JW (1983) Modeling reverse middle ear transmission of acoustic distortion signals Mechanics of Hearing: Proceedings of the IUTAM-ICA Symposium, de Boer E:Viergever MA, ed. pp.11
Meddis R, O'Mard LP, Lopez-Poveda EA (2001) A computational algorithm for computing nonlinear auditory frequency selectivity. J Acoust Soc Am 109:2852-61 [PubMed]
Miller RL, Calhoun BM, Young ED (1999) Contrast enhancement improves the representation of /epsilon/-like vowels in the hearing-impaired auditory nerve. J Acoust Soc Am 106:2693-708 [PubMed]
Miller RL, Schilling JR, Franck KR, Young ED (1997) Effects of acoustic trauma on the representation of the vowel "eh" in cat auditory nerve fibers. J Acoust Soc Am 101:3602-16 [PubMed]
Moller AR (1977) Frequency selectivity of single auditory-nerve fibers in response to broadband noise stimuli. J Acoust Soc Am 62:135-42 [PubMed]
Mountain DC, Cody AR (1999) Multiple modes of inner hair cell stimulation. Hear Res 132:1-14 [PubMed]
   Multiple modes of inner hair cell stimulation (Mountain, Cody 1999) [Model]
Narayan SS, Temchin AN, Recio A, Ruggero MA (1998) Frequency tuning of basilar membrane and auditory nerve fibers in the same cochleae. Science 282:1882-4 [PubMed]
Nuttall AL, Dolan DF (1993) Two-tone suppression of inner hair cell and basilar membrane responses in the guinea pig. J Acoust Soc Am 93:390-400 [PubMed]
Palmer AR, Russell IJ (1986) Phase-locking in the cochlear nerve of the guinea-pig and its relation to the receptor potential of inner hair-cells. Hear Res 24:1-15 [PubMed]
Patuzzi R (1996) Cochlear micromechanics and macromechanics The Cochlea, Dallos P:Popper AN:Fay RR, ed. pp.186
Patuzzi R, Robertson D (1988) Tuning in the mammalian cochlea. Physiol Rev 68:1009-82 [Journal] [PubMed]
Peake WT, Rosowski JJ, Lynch TJ (1992) Middle-ear transmission: acoustic versus ossicular coupling in cat and human. Hear Res 57:245-68 [PubMed]
Recio A, Narayan SS, Ruggero MA (1996) Wiener-kernel analysis of basilar membrane responses to noise. Diversity in Auditory Mechanics, Lewis ER:Long GR:Lyon RF:Narins PM:Steele CR:Hecht-Poinar E, ed. pp.325
Recio A, Rich NC, Narayan SS, Ruggero MA (1998) Basilar-membrane responses to clicks at the base of the chinchilla cochlea. J Acoust Soc Am 103:1972-89 [PubMed]
Rhode WS (1971) Observations of the vibration of the basilar membrane in squirrel monkeys using the Mössbauer technique. J Acoust Soc Am 49:Suppl 2:1218+ [PubMed]
Rhode WS (1973) An investigation of postmortem cochlear mechanics using the Mssbauer effects Basic Mechanisms in Hearing, Moller AR, ed. pp.49
Rhode WS, Recio A (2000) Study of mechanical motions in the basal region of the chinchilla cochlea. J Acoust Soc Am 107:3317-32 [PubMed]
Robert A, Eriksson JL (1999) A composite model of the auditory periphery for simulating responses to complex sounds. J Acoust Soc Am 106:1852-64 [PubMed]
Robertson D (1982) Effects of acoustic trauma on stereocilia structure and spiral ganglion cell tuning properties in the guinea pig cochlea. Hear Res 7:55-74 [PubMed]
Robles L, Rhode WS, Geisler CD (1976) Transient response of the basilar membrane measured in squirrel monkeys using the Mössbauer effect. J Acoust Soc Am 59:926-39 [PubMed]
Robles L, Ruggero MA (2001) Mechanics of the mammalian cochlea. Physiol Rev 81:1305-52 [Journal] [PubMed]
Ruggero MA, Rich NC (1983) Chinchilla auditory-nerve responses to low-frequency tones. J Acoust Soc Am 73:2096-2108 [PubMed]
Ruggero MA, Rich NC (1989) Peak splitting: Intensity effects in cochlear afferent responses to low frequency tones Cochlear Mechanisms: Structure, Function and Models, Wilson JP:Kemp DT, ed. pp.259
Ruggero MA, Rich NC, Recio A, Narayan SS, Robles L (1997) Basilar-membrane responses to tones at the base of the chinchilla cochlea. J Acoust Soc Am 101:2151-63 [PubMed]
Ruggero MA, Rich NC, Shivapuja BG, Temchin AN (1996) Auditory-nerve responses to low-frequency tones: Intensity dependence Aud Neurosci 2:159-185
Russell IJ, Sellick PM (1978) Intracellular studies of hair cells in the mammalian cochlea. J Physiol 284:261-90 [PubMed]
Sachs MB, Winslow RL, Sokolowski BH (1989) A computational model for rate-level functions from cat auditory-nerve fibers. Hear Res 41:61-9 [PubMed]
Salvi R, Perry J, Hamernik RP, Henderson D (1982) Relationships between cochlear pathologies and auditory nerve and behavioral responses following acoustic trauma New Perspectives on Noise-Induced Hearing Loss, Hamernik RP:Henderson D:Salvi R, ed. pp.165
Schmiedt RA, Zwislocki JJ, Hamernik RP (1980) Effects of hair cell lesions on responses of cochlear nerve fibers. I. Lesions, tuning curves, two-tone inhibition, and responses to trapezoidal-wave patterns. J Neurophysiol 43:1367-89 [Journal] [PubMed]
Schoonhoven R, Keijzer J, Versnel H, Prijs VF (1994) A dual filter model describing single-fiber responses to clicks in the normal and noise-damaged cochlea. J Acoust Soc Am 95:2104-21 [PubMed]
Sellick PM, Patuzzi R, Johnstone BM (1982) Measurement of basilar membrane motion in the guinea pig using the Mössbauer technique. J Acoust Soc Am 72:131-41 [PubMed]
Sewell WF (1984) The effects of furosemide on the endocochlear potential and auditory-nerve fiber tuning curves in cats. Hear Res 14:305-14 [PubMed]
Sewell WF (1984) Furosemide selectively reduces one component in rate-level functions from auditory-nerve fibers. Hear Res 15:69-72 [PubMed]
Shera CA (2001) Frequency glides in click responses of the basilar membrane and auditory nerve: their scaling behavior and origin in traveling-wave dispersion. J Acoust Soc Am 109:2023-34 [PubMed]
Simmons FB, Glattke TJ (1972) Comparison of electrical and acoustical stimulation of the cat ear. Ann Otol Rhinol Laryngol 81:731-7 [Journal] [PubMed]
Sumner CJ, O'Mard LP, Lopez-Poveda EA, Meddis R (2003) A nonlinear filter-bank model of the guinea-pig cochlear nerve: rate responses. J Acoust Soc Am 113:3264-74 [PubMed]
Tan Q, Carney LH (2003) A phenomenological model for the responses of auditory-nerve fibers. II. Nonlinear tuning with a frequency glide. J Acoust Soc Am 114:2007-20 [PubMed]
   Auditory nerve response model (Tan, Carney 2003) [Model]
Tchorz J, Kollmeier B (1999) A model of auditory perception as front end for automatic speech recognition. J Acoust Soc Am 106:2040-50 [PubMed]
van der Heijden M, Joris PX (2003) Cochlear phase and amplitude retrieved from the auditory nerve at arbitrary frequencies. J Neurosci 23:9194-8 [PubMed]
Westerman LA, Smith RL (1988) A diffusion model of the transient response of the cochlear inner hair cell synapse. J Acoust Soc Am 83:2266-76 [PubMed]
Wilson BS, Schatzer R, Lopez-Poveda EA, Sun X, Lawson DT, Wolford RD (2005) Two new directions in speech processor design for cochlear implants. Ear Hear 26:73S-81S [PubMed]
Wong JC (1998) Nonlinearities in the representation of the vowel - - in cat auditory nerve at sound levels near 100 dB SPL Master Thesis Johns Hopkins University
Wong JC, Miller RL, Calhoun BM, Sachs MB, Young ED (1998) Effects of high sound levels on responses to the vowel "eh" in cat auditory nerve. Hear Res 123:61-77 [PubMed]
Zhang X, Heinz MG, Bruce IC, Carney LH (2001) A phenomenological model for the responses of auditory-nerve fibers: I. Nonlinear tuning with compression and suppression. J Acoust Soc Am 109:648-70 [PubMed]
   Auditory nerve response model (Zhang et al 2001) [Model]
Davidson SA, Gilkey RH, Colburn HS, Carney LH (2009) An evaluation of models for diotic and dichotic detection in reproducible noises. J Acoust Soc Am 126:1906-25 [Journal] [PubMed]
   Models for diotic and dichotic detection (Davidson et al. 2009) [Model]
Peterson AJ, Heil P (2018) A simple model of the inner-hair-cell ribbon synapse accounts for mammalian auditory-nerve-fiber spontaneous spike times. Hear Res 363:1-27 [Journal] [PubMed]
Verhulst S, Altoè A, Vasilkov V (2018) Computational modeling of the human auditory periphery: Auditory-nerve responses, evoked potentials and hearing loss. Hear Res 360:55-75 [Journal] [PubMed]
   Human auditory periphery model: cochlea, IHC-AN, auditory brainstem responses (Verhulst et al 2018) [Model]
Zilany MS, Bruce IC (2007) Representation of the vowel /epsilon/ in normal and impaired auditory nerve fibers: model predictions of responses in cats. J Acoust Soc Am 122:402-17 [Journal] [PubMed]
   Cat auditory nerve model (Zilany and Bruce 2006, 2007) [Model]
Zilany MS, Bruce IC, Carney LH (2014) Updated parameters and expanded simulation options for a model of the auditory periphery. J Acoust Soc Am 135:283-6 [Journal] [PubMed]
   Cochlea: inner ear models in Python (Zilany et al 2009, 2014; Holmberg M 2007) [Model]
Zilany MS, Bruce IC, Nelson PC, Carney LH (2009) A phenomenological model of the synapse between the inner hair cell and auditory nerve: long-term adaptation with power-law dynamics. J Acoust Soc Am 126:2390-412 [Journal] [PubMed]
   Long-term adaptation with power-law dynamics (Zilany et al. 2009) [Model]
   Cochlea: inner ear models in Python (Zilany et al 2009, 2014; Holmberg M 2007) [Model]
(105 refs)