Title :
Training artificial neural networks with memristive synapses: HSPICE-matlab co-simulation
Author :
Aggarwal, A. ; Hamilton, Blaine
Author_Institution :
Univ. of Maryland, College Park, MD, USA
Abstract :
Researchers in the field of Neuromorphic Engineering are looking at ways to reduce the chip space required to mimic the huge processing capacity of the human brain and to simplify algorithms to train it. Since the recent fabrication of a memristor by the Hewlett Packard Company, there is a possibility to achieve both of these. With their crucial hysteresis properties, memristors can store charge during the training process and respond in a desired manner, electronically mimicking synapse behaviour. This arrangement can reduce chip space and potentially simplify the learning logic. This paper presents HSPICE modeling of an artificial neural network with memristive synapses and training it for `AND´ logic. An alternative modification of the memristor model was tried to simplify the learning logic. Results show potential for application in neural circuits.
Keywords :
SPICE; biocomputing; learning (artificial intelligence); logic gates; mathematics computing; memristors; neural chips; neurophysiology; AND logic; HSPICE modeling; HSPICE-Matlab cosimulation; Hewlett Packard Company; artificial neural network training; chip space reduction; human brain processing capacity; hysteresis properties; learning logic; memristive synapses; memristor fabrication; memristor model; neural circuits; neuromorphic engineering; synapse behaviour; Artificial neural networks; Integrated circuit modeling; MATLAB; Mathematical model; Memristors; Neurons; Training; Artificial Neural Networks; MATLAB-HSPICE coSimulation; Memristor;
Conference_Titel :
Neural Network Applications in Electrical Engineering (NEUREL), 2012 11th Symposium on
Conference_Location :
Belgrade
Print_ISBN :
978-1-4673-1569-2
DOI :
10.1109/NEUREL.2012.6419974
