Noise and neuronal populations conspire to encode simple waveforms reliably

Author

Parnas, Bruce R.

Author_Institution

Biocomputation Centre, NASA Ames Res. Center, Moffett Field, CA, USA

Volume

43

Issue

3

fYear

1996

fDate

3/1/1996 12:00:00 AM

Firstpage

313

Lastpage

318

Abstract

Sensory systems rely on populations of neurons to encode information transduced at the periphery into meaningful patterns of neuronal population activity. This transduction occurs in the presence of intrinsic neuronal noise. This is fortunate. The presence of noise allows more reliable encoding of the temporal structure present in the stimulus than would be possible in a noise-free environment. Simulations with a parallel model of signal processing at the auditory periphery have been used to explore the effects of noise and a neuronal population on the encoding of signal information. The results show that, for a given set of neuronal modeling parameters and stimulus amplitude, there is an optimal amount of noise for stimulus encoding with maximum fidelity.

Keywords

cellular biophysics; encoding; hearing; neurophysiology; physiological models; auditory periphery; intrinsic neuronal noise; maximum fidelity; meaningful patterns; neuronal modeling parameters; neuronal populations; reliable encoding; sensory systems; signal processing; simple waveforms encoding; stimulus amplitude; temporal structure; transduction; Encoding; Neurons; Noise generators; Noise level; Noise reduction; Nonlinear distortion; Phase noise; Signal processing; Stochastic resonance; Working environment noise; Action Potentials; Animals; Artifacts; Humans; Models, Neurological; Neurons; Time Factors; Vestibulocochlear Nerve;

fLanguage

English

Journal_Title

Biomedical Engineering, IEEE Transactions on

Publisher

ieee

ISSN

0018-9294

Type

jour

DOI

10.1109/10.486289

Filename

486289