Binary operations on neuromorphic hardware with application to linear algebraic operations and stochastic equations

Binary operations on neuromorphic hardware with application to linear algebraic operations and stochastic equations

Abstract Non-von Neumann computational hardware, based on neuron-inspired, non-linear elements connected via linear, weighted synapses—so-called neuromorphic systems—is a viable computational substrate. Since neuromorphic systems have been shown to use less power than CPUs for many applications, the...

Full description

Saved in:
Bibliographic Details
Published in:Neuromorphic computing and engineering Vol. 3; no. 1; pp. 14002 - 14018
Main Authors: Iaroshenko, Oleksandr, Sornborger, Andrew T, Chavez Arana, Diego
Format: Journal Article
Language:English
Published: United Kingdom IOP Publishing 01-03-2023
Subjects:
binary operation
matrix multiplication
random walk
spiking algorithm
two’s complement
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract Non-von Neumann computational hardware, based on neuron-inspired, non-linear elements connected via linear, weighted synapses—so-called neuromorphic systems—is a viable computational substrate. Since neuromorphic systems have been shown to use less power than CPUs for many applications, they are of potential use in autonomous systems such as robots, drones, and satellites, for which power resources are at a premium. The power used by neuromorphic systems is approximately proportional to the number of spiking events produced by neurons on-chip. However, typical information encoding on these chips is in the form of firing rates that unarily encode information. That is, the number of spikes generated by a neuron is meant to be proportional to an encoded value used in a computation or algorithm. Unary encoding is less efficient (produces more spikes) than binary encoding. For this reason, here we present neuromorphic computational mechanisms for implementing binary two’s complement operations. We use the mechanisms to construct a neuromorphic, binary matrix multiplication algorithm that may be used as a primitive for linear differential equation integration, deep networks, and other standard calculations. We also construct a random walk circuit and apply it in Brownian motion simulations. We study how both algorithms scale in circuit size and iteration time.
Bibliography:NCE-100134.R1
USDOE
SL20-ML-Neuromorphic-PD3Rs
ISSN:2634-4386
2634-4386
DOI:10.1088/2634-4386/aca7dd