Feedforward artificial neural network design utilising subthreshold mode CMOS devices

This thesis reviews various previously reported techniques for simulating artificial neural networks and investigates the design of fully-connected feedforward networks based on MOS transistors operating in the subthreshold mode of conduction as they are suitable for performing compact, low power, i...

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Main Author: Coue, Dominique Xavier Henri Leon
Published: University of Plymouth 1997
Subjects:
Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.361897
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spelling ndltd-bl.uk-oai-ethos.bl.uk-3618972015-03-19T04:05:13ZFeedforward artificial neural network design utilising subthreshold mode CMOS devicesCoue, Dominique Xavier Henri Leon1997This thesis reviews various previously reported techniques for simulating artificial neural networks and investigates the design of fully-connected feedforward networks based on MOS transistors operating in the subthreshold mode of conduction as they are suitable for performing compact, low power, implantable pattern recognition systems. The principal objective is to demonstrate that the transfer characteristic of the devices can be fully exploited to design basic processing modules which overcome the linearity range, weight resolution, processing speed, noise and mismatch of components problems associated with weak inversion conduction, and so be used to implement networks which can be trained to perform practical tasks. A new four-quadrant analogue multiplier, one of the most important cells in the design of artificial neural networks, is developed. Analytical as well as simulation results suggest that the new scheme can efficiently be used to emulate both the synaptic and thresholding functions. To complement this thresholding-synapse, a novel current-to-voltage converter is also introduced. The characteristics of the well known sample-and-hold circuit as a weight memory scheme are analytically derived and simulation results suggest that a dummy compensated technique is required to obtain the required minimum of 8 bits weight resolution. Performance of the combined load and thresholding-synapse arrangement as well as an on-chip update/refresh mechanism are analytically evaluated and simulation studies on the Exclusive OR network as a benchmark problem are provided and indicate a useful level of functionality. Experimental results on the Exclusive OR network and a 'QRS' complex detector based on a 10:6:3 multilayer perceptron are also presented and demonstrate the potential of the proposed design techniques in emulating feedforward neural networks.621.3192CircuitsUniversity of Plymouthhttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.361897http://hdl.handle.net/10026.1/1633Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 621.3192
Circuits
spellingShingle 621.3192
Circuits
Coue, Dominique Xavier Henri Leon
Feedforward artificial neural network design utilising subthreshold mode CMOS devices
description This thesis reviews various previously reported techniques for simulating artificial neural networks and investigates the design of fully-connected feedforward networks based on MOS transistors operating in the subthreshold mode of conduction as they are suitable for performing compact, low power, implantable pattern recognition systems. The principal objective is to demonstrate that the transfer characteristic of the devices can be fully exploited to design basic processing modules which overcome the linearity range, weight resolution, processing speed, noise and mismatch of components problems associated with weak inversion conduction, and so be used to implement networks which can be trained to perform practical tasks. A new four-quadrant analogue multiplier, one of the most important cells in the design of artificial neural networks, is developed. Analytical as well as simulation results suggest that the new scheme can efficiently be used to emulate both the synaptic and thresholding functions. To complement this thresholding-synapse, a novel current-to-voltage converter is also introduced. The characteristics of the well known sample-and-hold circuit as a weight memory scheme are analytically derived and simulation results suggest that a dummy compensated technique is required to obtain the required minimum of 8 bits weight resolution. Performance of the combined load and thresholding-synapse arrangement as well as an on-chip update/refresh mechanism are analytically evaluated and simulation studies on the Exclusive OR network as a benchmark problem are provided and indicate a useful level of functionality. Experimental results on the Exclusive OR network and a 'QRS' complex detector based on a 10:6:3 multilayer perceptron are also presented and demonstrate the potential of the proposed design techniques in emulating feedforward neural networks.
author Coue, Dominique Xavier Henri Leon
author_facet Coue, Dominique Xavier Henri Leon
author_sort Coue, Dominique Xavier Henri Leon
title Feedforward artificial neural network design utilising subthreshold mode CMOS devices
title_short Feedforward artificial neural network design utilising subthreshold mode CMOS devices
title_full Feedforward artificial neural network design utilising subthreshold mode CMOS devices
title_fullStr Feedforward artificial neural network design utilising subthreshold mode CMOS devices
title_full_unstemmed Feedforward artificial neural network design utilising subthreshold mode CMOS devices
title_sort feedforward artificial neural network design utilising subthreshold mode cmos devices
publisher University of Plymouth
publishDate 1997
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.361897
work_keys_str_mv AT couedominiquexavierhenrileon feedforwardartificialneuralnetworkdesignutilisingsubthresholdmodecmosdevices
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