Title :
Resistive-Type CVNS Distributed Neural Networks With Improved Noise-to-Signal Ratio
Author :
Khodabandehloo, Golnar ; Mirhassani, Mitra ; Ahmadi, Majid
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of Windsor, Windsor, ON, Canada
Abstract :
Resistive-type distributed neural networks (DNNs) provide a self-scaling structure for the neuron, which can spontaneously adapt itself to different numbers of inputs. In lumped neural networks, the neuron should be changed whenever the number of inputs changes due to the applications; redesigning the neuron is not practical, particularly for hardware implementations. In this brief, a group of feedforward DNNs based on a continuous valued number system is proposed, which outperforms not only the lumped neural networks but also the conventional DNNs because of the reduced sensitivity to noise.
Keywords :
continuous systems; distributed control; feedforward neural nets; redundant number systems; continuous valued number system; feedforward distributed neural network; improved noise to signal ratio; neuron; resistive type CVNS distributed neural network; self-scaling structure; Artificial neural networks; Equations; Indexes; Mathematical model; Neurons; Noise; Scalability; CVNS neural network; Continuous valued number system (CVNS) multiplication; distributed neural network (DNN); noise-to-signal ratio (NSR);
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2010.2067775
