A Software-equivalent SNN Hardware using RRAM-array for Asynchronous Real-time Learning
Abstract
Spiking Neural Network (SNN) naturally inspires hardware implementation as it is based on biology. For learning, spike time dependent plasticity (STDP) may be implemented using an energy efficient waveform superposition on memristor based synapse. However, system level implementation has three challenges. First, a classic dilemma is that recognition requires current reading for short voltagespikes which is disturbed by large voltagewaveforms that are simultaneously applied on the same memristor for realtime learning i.e. the simultaneous readwrite dilemma. Second, the hardware needs to exactly replicate software implementation for easy adaptation of algorithm to hardware. Third, the devices used in hardware simulations must be realistic. In this paper, we present an approach to address the above concerns. First, the learning and recognition occurs in separate arrays simultaneously in realtime, asynchronously avoiding nonbiomimetic clocking based complex signal management. Second, we show that the hardware emulates software at every stage by comparison of SPICE (circuitsimulator) with MATLAB (mathematical SNN algorithm implementation in software) implementations. As an example, the hardware shows 97.5 per cent accuracy in classification which is equivalent to software for a FisherIris dataset. Third, the STDP is implemented using a model of synaptic device implemented using HfO2 memristor. We show that an increasingly realistic memristor model slightly reduces the hardware performance (85 per cent), which highlights the need to engineer RRAM characteristics specifically for SNN.
Cite
@article{arxiv.1704.02012,
title = {A Software-equivalent SNN Hardware using RRAM-array for Asynchronous Real-time Learning},
author = {Aditya Shukla and Vinay Kumar and Udayan Ganguly},
journal= {arXiv preprint arXiv:1704.02012},
year = {2017}
}
Comments
Eight pages, ten figures and two tables