Pitch Representations in the Auditory Nerve: Two Concurrent Complex Tones

Larsen, Erik; Cedolin, Leonardo; Delgutte, Bertrand

doi:10.1152/jn.01361.2007

Cited by 48 publications

(63 citation statements)

References 88 publications

(197 reference statements)

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“…A periodic sieve (or template) was then defined by placing narrow bins (with binwidth=50 microseconds) at every integer multiple of the template period in the pooled ACF. Template contrast at a given template period (1/ template F0) was the ratio of the mean value in the periodic sieve to the overall mean of the pooled ACF (Larsen et al 2008). Template contrast was then computed for various template periods ranging from 80 to 1,000 Hz.…”

Section: Motivation and Rationale For The Modeling Approachmentioning

confidence: 99%

Computational Model Predictions of Cues for Concurrent Vowel Identification

Chintanpalli

Ahlstrom

Dubno

2014

JARO

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Although differences in fundamental frequencies (F0s) between vowels are beneficial for their segregation and identification, listeners can still segregate and identify simultaneous vowels that have identical F0s, suggesting that additional cues are contributing, including formant frequency differences. The current perception and computational modeling study was designed to assess the contribution of F0 and formant difference cues for concurrent vowel identification. Younger adults with normal hearing listened to concurrent vowels over a wide range of levels (25-85 dB SPL) for conditions in which F0 was the same or different between vowel pairs. Vowel identification scores were poorer at the lowest and highest levels for each F0 condition, and F0 benefit was reduced at the lowest level as compared to higher levels. To understand the neural correlates underlying level-dependent changes in vowel identification, a computational auditory-nerve model was used to estimate formant and F0 difference cues under the same listening conditions. Template contrast and average localized synchronized rate predicted level-dependent changes in the strength of phase locking to F0s and formants of concurrent vowels, respectively. At lower levels, poorer F0 benefit may be attributed to poorer phase locking to both F0s, which resulted from lower firing rates of auditory-nerve fibers. At higher levels, poorer identification scores may relate to poorer phase locking to the second formant, due to synchrony capture by lower formants. These findings suggest that concurrent vowel identification may be partly influenced by level-dependent changes in phase locking of auditory-nerve fibers to F0s and formants of both vowels.

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Section: Motivation and Rationale For The Modeling Approachmentioning

confidence: 99%

Computational Model Predictions of Cues for Concurrent Vowel Identification

Chintanpalli

Ahlstrom

Dubno

2014

JARO

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“…To estimate the neural pitch salience of each musical interval, each ACF pop was analyzed using "periodic template" analysis. A series of periodic sieves were applied to each ACF pop in order to quantify the neural activity at a given pitch period and its integer related multiples (Cedolin and Delgutte, 2005;Larsen et al, 2008;Bidelman and Krishnan, 2009). This periodic sieve analysis is essentially a time-domain equivalent to the classic pattern recognition models of pitch in which a "central pitch processor" matches harmonic information contained in the stimulus to an internal template in order to compute the heard pitch (Goldstein, 1973;Terhardt et al, 1982).…”

Section: Presentation Levelsmentioning

confidence: 99%

Auditory-nerve responses predict pitch attributes related to musical consonance-dissonance for normal and impaired hearing

Bidelman

Heinz²

2011

The Journal of the Acoustical Society of America

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Human listeners prefer consonant over dissonant musical intervals and the perceived contrast between these classes is reduced with cochlear hearing loss. Population-level activity of normal and impaired model auditory-nerve (AN) fibers was examined to determine (1) if peripheral auditory neurons exhibit correlates of consonance and dissonance and (2) if the reduced perceptual difference between these qualities observed for hearing-impaired listeners can be explained by impaired AN responses. In addition, acoustical correlates of consonance-dissonance were also explored including periodicity and roughness. Among the chromatic pitch combinations of music, consonant intervals/chords yielded more robust neural pitch-salience magnitudes (determined by harmonicity/ periodicity) than dissonant intervals/chords. In addition, AN pitch-salience magnitudes correctly predicted the ordering of hierarchical pitch and chordal sonorities described by Western music theory. Cochlear hearing impairment compressed pitch salience estimates between consonant and dissonant pitch relationships. The reduction in contrast of neural responses following cochlear hearing loss may explain the inability of hearing-impaired listeners to distinguish musical qualia as clearly as normal-hearing individuals. Of the neural and acoustic correlates explored, AN pitch salience was the best predictor of behavioral data. Results ultimately show that basic pitch relationships governing music are already present in initial stages of neural processing at the AN level.

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“…DPs have been extensively studied, but most of the focus has been at the level of the cochlea (Kim et al, 1980). Less is known about human subcortical processing of harmonically complex musical intervals (Fishman et al, 2000(Fishman et al, , 2001Tramo et al, 2001;Larsen et al, 2008). Our current research explores this topic by measuring the brainstem responses to consonant and dissonant intervals in musically trained and control subjects.…”

Section: Introductionmentioning

confidence: 99%

Selective Subcortical Enhancement of Musical Intervals in Musicians

Skoe²,

et al. 2009

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By measuring the auditory brainstem response to two musical intervals, the major sixth (E3 and G2) and the minor seventh (E3 and F#2), we found that musicians have a more specialized sensory system for processing behaviorally relevant aspects of sound. Musicians had heightened responses to the harmonics of the upper tone (E), as well as certain combination tones (sum tones) generated by nonlinear processing in the auditory system. In music, the upper note is typically carried by the upper voice, and the enhancement of the upper tone likely reflects musicians' extensive experience attending to the upper voice. Neural phase locking to the temporal periodicity of the amplitude-modulated envelope, which underlies the perception of musical harmony, was also more precise in musicians than nonmusicians. Neural enhancements were strongly correlated with years of musical training, and our findings, therefore, underscore the role that long-term experience with music plays in shaping auditory sensory encoding.

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Pitch Representations in the Auditory Nerve: Two Concurrent Complex Tones

Cited by 48 publications

References 88 publications

Computational Model Predictions of Cues for Concurrent Vowel Identification

Computational Model Predictions of Cues for Concurrent Vowel Identification

Auditory-nerve responses predict pitch attributes related to musical consonance-dissonance for normal and impaired hearing

Selective Subcortical Enhancement of Musical Intervals in Musicians

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