Silicon Implementation of Pulse Coded Neural Networks

When confronted with the hows and whys of nature's computational engines, some prefer to focus upon neural function: addressing issues of neural system behavior and its relation to natural intelligence. Then there are those who prefer the study of the "mechanics" of neural systems: the nuts and bolts of the "wetware": the neurons and synapses. Those who investigate pulse coded implementations ofartificial neural networks know what it means to stand at the boundary which lies between these two worlds: not just asking why natural neural systems behave as they do, but also how they achieve their marvelous feats. The research results presented in this book not only address more conventional abstract notions of neural-like processing, but also the more specific details ofneural-like processors. It has been established for some time that natural neural systems perform a great deal of information processing via electrochemical pulses. Accordingly, pulse coded neural network concepts are receiving increased attention in artificial neural network research. This increased interest is compounded by continuing advances in the field of VLSI circuit design. This is the first time in history in which it is practical to construct networks of neuron-like circuits of reasonable complexity that can be applied to real problems. We believe that the pioneering work in artificial neural systems presented in this book will lead to further advances that will not only be useful in some practical sense, but may also provide some additional insight into the operation of their natural counterparts.

Klappentext

When confronted with the how's and why's of nature's computational engines, some prefer to focus upon neural function: addressing issues of neural system behavior and its relation to natural intelligence. Then there are those who prefer the study of the mechanics' of neural systems: the nuts and bolts of the wetware': the neurons and synapses. Those who investigate pulse coded implementations of artificial neural networks know what it means to stand at the boundary which lies between these two worlds: not just asking why natural neural systems behave as they do, but also how they achieve their marvelous feats. The state-of-the-art research results presented in emSilicon/em emImplementation of Pulse Coded Neural Networks/em not only address more conventional abstract notions of neural-like processing, but also the more specific details of neural-like emprocessors./em br/ It has been established for some time that natural neural systems perform a great deal of information processing via electrochemical pulses. Accordingly, pulse coded neural network concepts are receiving increased attention in artificial neural network research. This increased interest is compounded by continuing advances in the field of VLSI circuit design. For the first time in history, it is practical to construct networks of neuron-like circuits of reasonable complexity that can be applied to real problems. The pioneering work in artificial neural systems presented in emSilicon Implementation of/em emPulse Coded Neural Networks/em will lead to further advances that will not only be useful in some practical sense, but may also provide some additional insight into the operation of their natural counterparts. br/ emSilicon Implementation of Pulse Coded Neural Networks/em seeks to cover many of the relevant contemporary studies coming out of this newly emerging area. As such, it serves as an excellent reference, and may be used as a text for advanced courses on the subject. br/

Inhalt

1. Some Historical Perspectives on EarlyPulse Coded Neural Network Circuits.- 2. Pulse Techniques in Neural VLSI: A Revie.- 3. Silicon Dendritic Trees.- 4. Silicon Neurons for Phase and FrequencyDetection and Pattern Generation.- 5. Pulse Coded Winner-Take-All Networks.- 6. Realization of Boolean Functions Usinga Pulse Coded Neuron.- 7. Design of Pulse Coded Neural ProcessingElement Using Modified Neural Type Cells.- 8. Low-Power Silicon Neurons, Axonsand Synapses.- 9. Synchronous Pulse Density Modulationin Neural Network Implementation.- 10. CMOS Analog Neural Network Systems Based on Oscillatory Neurons.- 11. A Digital Neural Network Architecture Using Random Pulse Trains.- 12. An Unsupervised Neural Processor.