Performance Evaluation of Spintronic-Based Spiking Neural Networks Using Parallel Discrete-Event Simulation

Abstract

Spintronics devices that use the spin of electrons as the information state variable have the potential to emulate neuro-synaptic dynamics and can be realized within a compact form-factor, while operating at ultra-low energy-delay point. In this paper, we benchmark the performance of a spintronics hardware platform designed for handling neuromorphic tasks. To explore the benefits of spintronics-based hardware on realistic neuromorphic workloads, we developed a Parallel Discrete-Event Simulation model called Doryta, which is further integrated with a materials-to-systems benchmarking framework. The benchmarking framework allows us to obtain quantitative metrics on the throughput and energy of spintronics-based neuromorphic computing and compare these against standard CMOS-based approaches. Although spintronics hardware offers significant energy and latency advantages, we find that for larger neuromorphic circuits, the performance is limited by the interconnection networks rather than the spintronics-based neurons and synapses. This limitation can be overcome by architectural changes to the network. Through Doryta we are also able to show the power of neuromorphic computing by simulating Conway’s Game of Life (GoL), thus showing that it is Turing complete. We show that Doryta obtains over 300 × speedup using 1,024 CPU cores when tested on a convolutional, sparse, neural architecture. When scaled-up 64 times, to a 200 million neuron model, the simulation ran in 3:42 minutes for a total of 2000 virtual clock steps. The conservative approach of execution was found to be faster in most cases than the optimistic approach, even when a tie-breaking mechanism to guarantee deterministic execution, was deactivated.