On-Chip Trainable 1.4M 6T2R PCM Synaptic Array with 1.6K Stochastic LIF Neurons for Spiking RBM
2019 IEEE International Electron Devices Meeting (IEDM)(2019)
摘要
A fully silicon-integrated restricted Boltzmann machine (RBM) with event-driven contrastive divergence (eCD) algorithm is implemented using novel stochastic leaky integrate-and-fire (LIF) neuron circuits and 6-transistor/2- PCM-resistor (6T2R) unit cells on 90-nm CMOS technology. A bidirectional asynchronous spiking signaling scheme over an analog-weighted phase change memory (PCM) crossbar enables spike-timing-dependent plasticity (STDP) as a local weight update rule. This results in concurrent massively- parallel neuronal computation for low-power on-chip training and inference. Experimental image classification using 100 handwritten digit images from the MNIST database demonstrates 92% training accuracy. SPICE simulation abstracted from the fabricated design indicates 8.95 power. A projection to 28-nm technology gives 5.39 pJ per synaptic operation.
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关键词
1.6k stochastic LIF neurons,spiking RBM,Boltzmann machine,event-driven contrastive divergence algorithm,PCM-resistor unit cells,90-nm CMOS technology,bidirectional asynchronous spiking signaling scheme,analog-weighted phase change memory,spike-timing-dependent plasticity,local weight update rule,parallel neuronal computation,on-chip training,experimental image classification,handwritten digit images,28-nm technology,on-chip trainable 1.4M 6T2R PCM synaptic array,stochastic leaky integrate-and-fire neuron circuits,6-transistor/2- PCM-resistor unit cells,SPICE simulation
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