By Fourier's theorem, signals can be decomposed into a sum of sinusoids
of different frequencies. This is especially relevant for hearing,
because the inner ear performs a form of mechanical Fourier transform
by mapping frequencies along the length of the cochlear partition.
An alternative signal decomposition, originated by Hilbert, is to
factor a signal into the product of a slowly varying envelope and
a rapidly varying fine time structure. Neurons in the auditory brainstem
sensitive to these features have been found in mammalian physiological
studies. To investigate the relative perceptual importance of envelope
and fine structure, we synthesized stimuli that we call 'auditory
chimaeras', which have the envelope of one sound and the fine structure
of another. Here we show that the envelope is most important for
speech reception, and the fine structure is most important for pitch
perception and sound localization. When the two features are in conflict,
the sound of speech is heard at a location determined by the fine
structure, but the words are identified according to the envelope.
This finding reveals a possible acoustic basis for the hypothesized
'what' and 'where' pathways in the auditory cortex.
%0 Journal Article
%1 Smith2002
%A Smith, Zachary M
%A Delgutte, Bertrand
%A Oxenham, Andrew J
%D 2002
%J Nature
%K Auditory Localization,Sound Localization: Perception,Auditory Perception,Pitch Perception,Speech Perception: Tests,Humans,Models,Neurological,Pitch physiology,English,Hearing physiology,Sound physiology,Speech physiology,acoustics,language,melody,music,perception,speech
%N 6876
%P 87--90
%R 10.1038/416087a
%T Chimaeric sounds reveal dichotomies in auditory perception
%U http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2268248&tool=pmcentrez&rendertype=abstract
%V 416
%X By Fourier's theorem, signals can be decomposed into a sum of sinusoids
of different frequencies. This is especially relevant for hearing,
because the inner ear performs a form of mechanical Fourier transform
by mapping frequencies along the length of the cochlear partition.
An alternative signal decomposition, originated by Hilbert, is to
factor a signal into the product of a slowly varying envelope and
a rapidly varying fine time structure. Neurons in the auditory brainstem
sensitive to these features have been found in mammalian physiological
studies. To investigate the relative perceptual importance of envelope
and fine structure, we synthesized stimuli that we call 'auditory
chimaeras', which have the envelope of one sound and the fine structure
of another. Here we show that the envelope is most important for
speech reception, and the fine structure is most important for pitch
perception and sound localization. When the two features are in conflict,
the sound of speech is heard at a location determined by the fine
structure, but the words are identified according to the envelope.
This finding reveals a possible acoustic basis for the hypothesized
'what' and 'where' pathways in the auditory cortex.
@article{Smith2002,
abstract = {By Fourier's theorem, signals can be decomposed into a sum of sinusoids
of different frequencies. This is especially relevant for hearing,
because the inner ear performs a form of mechanical Fourier transform
by mapping frequencies along the length of the cochlear partition.
An alternative signal decomposition, originated by Hilbert, is to
factor a signal into the product of a slowly varying envelope and
a rapidly varying fine time structure. Neurons in the auditory brainstem
sensitive to these features have been found in mammalian physiological
studies. To investigate the relative perceptual importance of envelope
and fine structure, we synthesized stimuli that we call 'auditory
chimaeras', which have the envelope of one sound and the fine structure
of another. Here we show that the envelope is most important for
speech reception, and the fine structure is most important for pitch
perception and sound localization. When the two features are in conflict,
the sound of speech is heard at a location determined by the fine
structure, but the words are identified according to the envelope.
This finding reveals a possible acoustic basis for the hypothesized
'what' and 'where' pathways in the auditory cortex.},
added-at = {2011-03-27T17:20:41.000+0200},
author = {Smith, Zachary M and Delgutte, Bertrand and Oxenham, Andrew J},
biburl = {https://www.bibsonomy.org/bibtex/2a2a6caa145142e5c9be30f284fcb8ec9/yevb0},
doi = {10.1038/416087a},
file = {:Smith, Delgutte, Oxenham_2002_Chimaeric sounds reveal dichotomies in auditory perception.pdf:PDF},
interhash = {81d11a29d63f1675d718550066dfb4d4},
intrahash = {a2a6caa145142e5c9be30f284fcb8ec9},
issn = {0028-0836},
journal = {Nature},
keywords = {Auditory Localization,Sound Localization: Perception,Auditory Perception,Pitch Perception,Speech Perception: Tests,Humans,Models,Neurological,Pitch physiology,English,Hearing physiology,Sound physiology,Speech physiology,acoustics,language,melody,music,perception,speech},
mendeley-tags = {English,acoustics,language,melody,music,perception,speech},
month = mar,
number = 6876,
pages = {87--90},
pmid = {11882898},
timestamp = {2011-03-27T17:21:07.000+0200},
title = {Chimaeric sounds reveal dichotomies in auditory perception},
url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2268248\&tool=pmcentrez\&rendertype=abstract},
volume = 416,
year = 2002
}