Title :
A neuromorphic approach to adaptive digital circuitry
Author :
Walker, M.R. ; Akers, L.A.
Author_Institution :
Center for Solid State Electron. Res., Arizona State Univ., Tempe, AZ, USA
Abstract :
A design for an adaptive digital circuit based on neuromorphic (brain-inspired) architecture is proposed. The neuromorphic model used is a two-layered perceptron that utilizes a form of least-mean-square error correction in order to learn appropriate internal representations necessary to accomplish the mapping of binary input vectors into desired binary output vectors. The proposed network design differs from the theoretical model in that limited density between layers and quantized parameter values are used to facilitate VLSI fabrication. Simulation results indicate that the simplified version of the network behaves in ways similar to the fully connected, floating-point network with approximately the same number of elements in the middle layer. Circuits which are designed with neural-inspired, cellular topology would have the advantage of high fault tolerance, since information is stored in neural networks in a distributed, rather than a local, fashion
Keywords :
VLSI; adaptive systems; cellular arrays; digital circuits; error correction; learning systems; least squares approximations; neural nets; parallel architectures; VLSI fabrication; adaptive digital circuit; brain-like architecture; cellular topology; fault tolerance; learning; least-mean-square error correction; neural networks; neuromorphic architecture; two-layered perceptron; Cellular networks; Circuit simulation; Circuit topology; Digital circuits; Error correction; Fabrication; Multilayer perceptrons; Network topology; Neuromorphics; Very large scale integration;
Conference_Titel :
Computers and Communications, 1988. Conference Proceedings., Seventh Annual International Phoenix Conference on
Conference_Location :
Scottsdale, AZ
Print_ISBN :
0-8186-0830-7
DOI :
10.1109/PCCC.1988.10037
