Title :
A universal digital VLSI design for neural networks
Author :
Fu, H.C. ; Hwang, J.N. ; Kung, S.Y. ; Vlontzos, J.A.
Author_Institution :
Dept. of Electr. Eng., Princeton Univ., NJ, USA
Abstract :
Summary form only given. A universal digital VLSI design is proposed for implementing a wide variety of artificial neural networks. A programmable systolic array is presented based on a unified iterative neural network model, which maximizes the strength of VLSI in terms of intensive and pipelined computing and yet circumvents the limitation on communication. The array is meant for a universal simulation tool and neurocomputer architecture which can implement a variety of algorithms in both the retrieving and the learning phases of ANNs, e.g. single-layer feedback networks, competitive learning networks, multilayer feedforward networks, and stochastic neural networks. A fault-tolerance approach and partitioning scheme for large or nonhomogeneous networks are also proposed.<>
Keywords :
VLSI; cellular arrays; learning systems; microprocessor chips; neural nets; pipeline processing; ANNs; competitive learning networks; fault-tolerance approach; learning phases; multilayer feedforward networks; neural networks; neurocomputer architecture; nonhomogeneous networks; partitioning scheme; pipelined computing; programmable systolic array; retrieving phases; single-layer feedback networks; stochastic neural networks; universal digital VLSI design; universal simulation tool; Cellular logic arrays; Learning systems; Microprocessors; Neural networks; Pipeline processing; Very-large-scale integration;
Conference_Titel :
Neural Networks, 1989. IJCNN., International Joint Conference on
Conference_Location :
Washington, DC, USA
DOI :
10.1109/IJCNN.1989.118453
