A Gaussian synapse circuit for analog VLSI neural networks

Author

Choi, Joongho ; Sheu, Bing J. ; Chang, Josephine C F

Author_Institution

Dept. of Electr. Eng., Univ. of Southern California, Los Angeles, CA, USA

Volume

2

Issue

1

fYear

1994

fDate

3/1/1994 12:00:00 AM

Firstpage

129

Lastpage

133

Abstract

Back-propagation neural networks with Gaussian function synapses have better convergence property over those with linear-multiplying synapses. In digital simulation, more computing time is spent on Gaussian function evaluation. We present a compact analog synapse cell which is not biased in the subthreshold region for fully-parallel operation. This cell can approximate a Gaussian function with accuracy around 98% in the ideal case. Device mismatch induced by fabrication process will cause some degradation to this approximation. The Gaussian synapse cell can also be used in unsupervised learning. Programmability of the proposed Gaussian synapse cell is achieved by changing the stored synapse weight W/sub ji/, the reference current and the sizes of transistors in the differential pair.<>

Keywords

CMOS integrated circuits; VLSI; analogue processing circuits; backpropagation; convergence; function approximation; linear integrated circuits; neural chips; parallel processing; unsupervised learning; CMOS VLSI; Gaussian function approximation; Gaussian synapse circuit; analog VLSI neural networks; back-propagation neural networks; compact analog synapse cell; convergence property; differential pair; fully-parallel operation; programmability; reference current; stored synapse weight; unsupervised learning; Artificial neural networks; Circuits; Convergence; Degradation; Digital simulation; Fabrication; Neural networks; Neurons; Transfer functions; Very large scale integration;

fLanguage

English

Journal_Title

Very Large Scale Integration (VLSI) Systems, IEEE Transactions on

Publisher

ieee

ISSN

1063-8210

Type

jour

DOI

10.1109/92.273156

Filename

273156