Abstract

Spiking neural networks (SNN) are computational models inspired by the brain’s ability to naturally encode and process information in the time domain. The added temporal dimension is believed to render them more computationally efficient than the conventional artificial neural networks, though their full computational capabilities are yet to be explored. Recently, in-memory computing architectures based on non-volatile memory crossbar arrays have shown great promise to implement parallel computations in artificial and spiking neural networks. In this work, we evaluate the feasibility to realize high-performance event-driven in-situ supervised learning systems using nanoscale and stochastic analog memory synapses. For the first time, the potential of analog memory synapses to generate precisely timed spikes in SNNs is experimentally demonstrated. The experiment targets applications which directly integrates spike encoded signals generated from bio-mimetic sensors with in-memory computing based learning systems to generate precisely timed control signal spikes for neuromorphic actuators. More than 170,000 phase-change memory (PCM) based synapses from our prototype chip were trained based on an event-driven learning rule, to generate spike patterns with more than 85% of the spikes within a 25 ms tolerance interval in a 1250 ms long spike pattern. We observe that the accuracy is mainly limited by the imprecision related to device programming and temporal drift of conductance values. We show that an array level scaling scheme can significantly improve the retention of the trained SNN states in the presence of conductance drift in the PCM. Combining the computational potential of supervised SNNs with the parallel compute power of in-memory computing, this work paves the way for next-generation of efficient brain-inspired systems.

Highlights

  • The size and complexity of artificial neural networks are expected to grow in the future and has motivated the search for efficient and scalable hardware implementation schemes for learning systems[1]

  • Our work experimentally evaluates the task of supervised training to generate precisely timed spikes when the Spiking neural networks (SNN) synapses are implemented using phase-change memory (PCM) devices

  • Our work provides an experimental evaluation of the ability of phase-change memory devices to represent the synaptic strength in SNNs that have been trained to create spikes at precise time instances

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Summary

Introduction

The size and complexity of artificial neural networks are expected to grow in the future and has motivated the search for efficient and scalable hardware implementation schemes for learning systems[1]. Application specific integrated circuit (ASIC) designs such as TrueNorth from IBM3 and Loihi from Intel[4] that implement SNN dynamics have been successful in demonstrating two to three orders of magnitude energy efficiency gain by using such sparse, asynchronous, and event-driven computations These fully digital implementations use area expensive static random access memory (SRAM) circuits for synaptic weight storage which could potentially limit the amount of memory that can be integrated on-chip and the scalability of these architectures. Our work experimentally evaluates the task of supervised training to generate precisely timed spikes when the SNN synapses are implemented using phase-change memory (PCM) devices. We experimentally demonstrate that the SNN response can be maintained over a period of 4 days on PCM hardware in the presence of conductance drift using a global scaling technique without significant loss in spike time accuracy

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