DocumentCode
3391590
Title
Shunting networks for multi-band AM-FM-decomposition
Author
Baxter, Robert A. ; Quatieri, Thomas F.
Author_Institution
Baxter Res., Bedford, MA, USA
fYear
1999
fDate
1999
Firstpage
227
Lastpage
230
Abstract
We describe a transduction-based, neurodynamic approach to estimating the amplitude-modulated (AM) and frequency-modulated (FM) components of a signal. We show that the transduction approach can be realized as a bank of constant-Q bandpass filters followed by envelope detectors and shunting neural networks, and the resulting dynamical system is capable of robust AM-FM estimation. Our model is consistent with previous psychophysical experiments that indicate AM and FM components of acoustic signals may be transformed into a common neural code in the brain stem via FM-to-AM transduction (Saberi and Hafter 1995). The shunting network for AM-FM decomposition is followed by a contrast enhancement shunting network that provides a mechanism for robustly selecting auditory filter channels as the FM of an input stimulus sweeps across the multiple filters. The AM-FM output of the shunting networks may provide a robust feature representation and is being considered for applications in signal recognition and multi-component decomposition problems
Keywords
acoustic filters; acoustic signal processing; amplitude estimation; amplitude modulation; channel bank filters; frequency estimation; frequency modulation; hearing; neural nets; AM-FM estimation; acoustic signals; amplitude-modulated component; auditory filter channels; brain stem; common neural code; constant-Q bandpass filters; contrast enhancement shunting network; dynamical system; envelope detectors; frequency-modulated component; multi-band AM-FM-decomposition; multi-component decomposition problems; psychophysical experiments; robust feature representation; shunting neural networks; signal recognition; transduction-based neurodynamic approach; Biological neural networks; Brain modeling; Ear; Envelope detectors; Filters; Frequency modulation; Neurodynamics; Passband; Psychology; Robustness;
fLanguage
English
Publisher
ieee
Conference_Titel
Applications of Signal Processing to Audio and Acoustics, 1999 IEEE Workshop on
Conference_Location
New Paltz, NY
Print_ISBN
0-7803-5612-8
Type
conf
DOI
10.1109/ASPAA.1999.810891
Filename
810891
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