TY - GEN
T1 - Randomly reconfigurable cellular neural network
AU - Ayhan, Tuba
AU - Yalçin, Müştak Erhan
PY - 2011
Y1 - 2011
N2 - Biological networks involve both regular and random connections. Moreover they employ more than one type of cells. Being widely used in bio-inspired systems, Cellular Neural Networks are practical to implement large networks due to their regularly defined connections between unit processors. However, this perfect regularity of the structure does not always match with applications. Although it is widely selected for retina like demonstrations itself, there is an absence of CNN for using it in other bio-inspired systems: an ordinary CNN has only one type of unit processor in one layer. However, sensory data processing in nature mainly depend on the collaboration of distinct dynamics. Neural mass models are suggested to mimic the joint effort of distinct types of neurons and they are widely used to simulate and understand brain activity. The regularity of an ordinary CNN benefits in implementation of the network. While protecting this simplicity, in this work, we propose a method to build a single layer cellular neural network that can perform a Wilson-Cowan like neural population model.
AB - Biological networks involve both regular and random connections. Moreover they employ more than one type of cells. Being widely used in bio-inspired systems, Cellular Neural Networks are practical to implement large networks due to their regularly defined connections between unit processors. However, this perfect regularity of the structure does not always match with applications. Although it is widely selected for retina like demonstrations itself, there is an absence of CNN for using it in other bio-inspired systems: an ordinary CNN has only one type of unit processor in one layer. However, sensory data processing in nature mainly depend on the collaboration of distinct dynamics. Neural mass models are suggested to mimic the joint effort of distinct types of neurons and they are widely used to simulate and understand brain activity. The regularity of an ordinary CNN benefits in implementation of the network. While protecting this simplicity, in this work, we propose a method to build a single layer cellular neural network that can perform a Wilson-Cowan like neural population model.
UR - http://www.scopus.com/inward/record.url?scp=80155132420&partnerID=8YFLogxK
U2 - 10.1109/ECCTD.2011.6043615
DO - 10.1109/ECCTD.2011.6043615
M3 - Conference contribution
AN - SCOPUS:80155132420
SN - 9781457706189
T3 - 2011 20th European Conference on Circuit Theory and Design, ECCTD 2011
SP - 604
EP - 607
BT - 2011 20th European Conference on Circuit Theory and Design, ECCTD 2011
T2 - 2011 20th European Conference on Circuit Theory and Design, ECCTD 2011
Y2 - 29 August 2011 through 31 August 2011
ER -