Topographic organization is essential for pitch perception
TLDR
Pitch is the perceptual attribute the authors associate most with melodies in music, patterns of bird songs, and the distinctions between speakers' voices, and is likely to change dramatically in favor of the place theories with the publication of results of intricately designed psychoacoustic experiments by Oxenham et al.Abstract:
Pitch is the perceptual attribute we associate most with melodies in music, patterns of bird songs, and the distinctions between speakers' voices. It plays a key role in the organization, segregation, and identification of sound sources in cluttered auditory scenes because it is derived from acoustic cues that closely reflect the material and geometric properties of resonating objects. Pitch has been the subject of intensive psychoacoustic studies for well over a century. In recent decades, physiological investigations in humans and animals have attempted to locate and understand the biological substrate underlying pitch perception at various levels of the auditory nervous system. However, despite all efforts, a deep understanding of the mechanisms that give rise to the pitch percept remains elusive. This uncertainty has generated passionate debates between the proponents of two very different theories of pitch, one based on the place or location of neural activation patterns, and the other on their temporal modulations. This state of affairs is now likely to change dramatically in favor of the place theories with the publication of results of intricately designed psychoacoustic experiments by Oxenham et al. (1) reported in this issue of PNAS.
There is universal agreement that pitch is basically a correlate of the periodicity of a sound waveform. The simplest such waveform is the pure tone (Fig. 1 A ); it is composed of a single sinusoid that gives rise to a pitch percept correlated with the frequency (or periodicity) of the sinusoid. A richer percept results when a complex periodic waveform is composed of several tones that are harmonically related, i.e., are integer multiples of a common fundamental frequency (Fig. 1 B ). Such a waveform evokes a salient and unified sense of pitch that we typically associate with the fundamental frequency regardless of the relative amplitudes of the harmonics, their dynamics, and …read more
Citations
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Journal ArticleDOI
A Neural Representation of Pitch Salience in Nonprimary Human Auditory Cortex Revealed with Functional Magnetic Resonance Imaging
TL;DR: Functional magnetic resonance imaging was used to measure activation in response to harmonic tone complexes whose temporal regularity was identical, but whose pitch salience differed, across conditions, contributing to converging evidence that anterior areas of nonprimary auditory cortex play an important role in processing pitch.
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The olfactory sensory map in Drosophila.
TL;DR: In vivo electrophysiology has been used to decode the ligand response profiles of most of the ORs, providing insight into the initial logic of olfactory coding in the fly.
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Landscapes, Houses, Bodies, Things: “Place” and the Archaeology of Inuit Imaginaries
TL;DR: The notion of imagaries and the rethinking of place are illustrated with Inuit archaeological and ethnographic examples as discussed by the authors, where places emerge as sites of the hybrid articulation of representations, practices, and things, as spatialized imaginaries.
Journal ArticleDOI
Phonological processing in adults with deficits in musical pitch recognition.
TL;DR: The results indicate that poor performance on the DTT is associated with deficits in processing speech sounds, and that tune deafness may be viewed as a syndromic disorder, frequently accompanied by deficits in a number of aspects of sound processing not specific to music.
Journal ArticleDOI
Cortical processing of pitch: Model-based encoding and decoding of auditory fMRI responses to real-life sounds
Vittoria De Angelis,Federico De Martino,Michelle Moerel,Roberta Santoro,Lars Hausfeld,Elia Formisano +5 more
TL;DR: This study investigated the neural representation of pitch in human auditory cortex using model‐based encoding and decoding analyses of high field functional magnetic resonance imaging (fMRI) data collected while participants listened to a wide range of real‐life sounds.
References
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An optimum processor theory for the central formation of the pitch of complex tones
TL;DR: A theory was formulated for the central formation of the pitch of complex tones, i.e., periodicity pitch, which is a logical deduction from statistical estimation theory of the optimal estimate for fundamental frequency.
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Journal ArticleDOI
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