CPL - Chalmers Publication Library
| Utbildning | Forskning | Styrkeområden | Om Chalmers | In English In English Ej inloggad.

Basic difference between brain and computer: Integration of asynchronous processes implemented as hardware model of the retina

A. W. Przybyszewski ; P. S. Linsay ; P. Gaudiano ; Christopher Wilson (Institutionen för mikroteknologi och nanovetenskap, Kvantkomponentfysik)
Ieee Transactions on Neural Networks (1045-9227). Vol. 18 (2007), 1, p. 70-85.
[Artikel, refereegranskad vetenskaplig]

There exists a common view that the brain acts like a Turing machine: The machine reads information from an infinite tape (sensory data) and, on the basis of the machine's state and information from the tape, an action (decision) is made. The main problem with this model lies in how to synchronize a large number of tapes in an adaptive way so that the machine is able to accomplish tasks such as object classification. We propose that such mechanisms exist already in the eye. A popular view is that the retina, typically associated with high gain and adaptation for light processing, is actually performing local preprocessing by means of its center-surround receptive field. We would like to show another property of the retina: The ability to integrate many independent processes. We believe that this integration is implemented by synchronization of neuronal oscillations. In this paper, we present a model of the retina consisting of a series of coupled oscillators which can synchronize on several scales. Synchronization is an analog process which is converted into a digital spike train in the output of the retina. We have developed a hardware implementation of this model, which enables us to carry out rapid simulation of multineuron oscillatory dynamics. We show that the properties of the spike trains in our model are similar to those found in vivo in the cat retina.

Denna post skapades 2008-12-23.
CPL Pubid: 82762


Läs direkt!

Länk till annan sajt (kan kräva inloggning)

Institutioner (Chalmers)

Institutionen för mikroteknologi och nanovetenskap, Kvantkomponentfysik


Elektroteknik och elektronik

Chalmers infrastruktur