One-Board Design and Simulation of Double-Layer Perceptron Based on Metal-Oxide Memristive Nanostructures

One-Board Design and Simulation of Double-Layer Perceptron Based on Metal-Oxide Memristive Nanostructures

Design and training principles have been proposed and tested for an artificial neural network based on metal-oxide thin-film nanostructures possessing bipolar resistive switching (memristive) effect. Experimental electronic circuit of neural network is implemented as a double-layer perceptron with a...

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Veröffentlicht in:IEEE transactions on emerging topics in computational intelligence 2018-10, Vol.2 (5), p.371-379
Hauptverfasser: Mikhaylov, Alexey N., Pigareva, Yana I., Pimashkin, Alexey S., Lobov, Sergey A., Kazantsev, Victor B., Morozov, Oleg A., Ovchinnikov, Pavel E., Antonov, Ivan N., Belov, Alexey I., Korolev, Dmitry S., Sharapov, Alexander N., Gryaznov, Evgeniy G., Gorshkov, Oleg N.
Format: Artikel
Sprache:eng
Schlagworte:
adaptive behavior
Algorithms
artificial neural network
Artificial neural networks
Biological neural networks
Circuits
Classification
Computer simulation
Dielectrics
Electrodes
Electronic circuits
Electronic devices
Hardware
Memory devices
memristive device
Memristors
Metal oxides
Metal-oxide nanostructure
Nanostructure
Nanostructures
Neural networks
neuromorphic system
neuronal activity
Resistance
resistive switching
Thin films
Weight
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Beschreibung
Zusammenfassung:Design and training principles have been proposed and tested for an artificial neural network based on metal-oxide thin-film nanostructures possessing bipolar resistive switching (memristive) effect. Experimental electronic circuit of neural network is implemented as a double-layer perceptron with a weight matrix composed of 32 memristive devices. The network training algorithm takes into account technological variations of the parameters of memristive devices. Despite the limited size of weight matrix the developed neural network model is scalable and capable of solving nonlinear classification problems. The learning and functionality of the network are demonstrated by using its computer model for the classification of activity propagation directions in simulated neuronal culture.
ISSN:2471-285X
2471-285X
DOI:10.1109/TETCI.2018.2829922