Encoding information in neural feedback circuits

Author

Mensour, Boualem ; Longtin, André

Author_Institution

Dept. of Phys., Ottawa Univ., Ont., Canada

Volume

2

fYear

1995

fDate

20-23 Sep 1995

Firstpage

1463

Abstract

Studies the storage of information in recurrent neural feedback circuits modeled by nonlinear delay-differential equations (DDE´s). The information is encoded into the initial function from which the DDE evolves into a periodic solution. We find that the Mackey-an der Heiden (MH) model of recurrent inhibition (RI), involving non-spiking neurons, has multistable periodic patterns of voltage, and thus of spike patterns. The spiking solutions of Plant´s model, based on the Fitzhugh-Nagumo equations, are also found to be encodable. Our approach offers a simple mechanism for active short-term memory based on the temporal patterns of a simple neural system rather than on the spatial properties of a neural network

Keywords

bioelectric potentials; biomembrane transport; brain models; encoding; feedback; neurophysiology; nonlinear differential equations; recurrent neural nets; Fitzhugh-Nagumo equations; Mackey-an der Heiden model; Plant model; active short-term memory; information encoding; information storage; initial function; membrane voltage; multistable periodic patterns; neural feedback circuits; neural network; nonlinear delay-differential equations; nonspiking neurons; periodic solution; recurrent inhibition; recurrent neural feedback circuits; simple neural system; spatial properties; spike patterns; spiking activity; temporal patterns; voltage; Biological neural networks; Delay effects; Encoding; Feedback circuits; Mechanical factors; Nervous system; Neurons; Nonlinear equations; Spinal cord; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society, 1995., IEEE 17th Annual Conference

Conference_Location

Montreal, Que.

Print_ISBN

0-7803-2475-7

Type

conf

DOI

10.1109/IEMBS.1995.579778

Filename

579778