# Autonomous Probabilistic Coprocessing with Petaflips per Second

**Authors:** Brian Sutton, Rafatul Faria, Lakshmi A. Ghantasala, Risi Jaiswal,, Kerem Y. Camsari, Supriyo Datta

arXiv: 1907.09664 · 2020-08-25

## TL;DR

This paper proposes a novel autonomous probabilistic computer architecture based on a network of p-bits, capable of ultrafast operation without sequencers, and projects petaflips per second scalability with hardware benchmarks.

## Contribution

It introduces a sequencerless design for probabilistic computers using p-bits, enabling ultrafast, autonomous operation and hardware-agnostic performance metrics.

## Key findings

- Demonstrates ultrafast autonomous p-bit operation
- Projects petaflips per second scalability with hardware benchmarks
- Proposes flips per second as a universal hardware performance metric

## Abstract

In this paper we present a concrete design for a probabilistic (p-) computer based on a network of p-bits, robust classical entities fluctuating between -1 and +1, with probabilities that are controlled through an input constructed from the outputs of other p-bits. The architecture of this probabilistic computer is similar to a stochastic neural network with the p-bit playing the role of a binary stochastic neuron, but with one key difference: there is no sequencer used to enforce an ordering of p-bit updates, as is typically required. Instead, we explore \textit{sequencerless} designs where all p-bits are allowed to flip autonomously and demonstrate that such designs can allow ultrafast operation unconstrained by available clock speeds without compromising the solution's fidelity. Based on experimental results from a hardware benchmark of the autonomous design and benchmarked device models, we project that a nanomagnetic implementation can scale to achieve petaflips per second with millions of neurons. A key contribution of this paper is the focus on a hardware metric $-$ flips per second $-$ as a problem and substrate-independent figure-of-merit for an emerging class of hardware annealers known as Ising Machines. Much like the shrinking feature sizes of transistors that have continually driven Moore's Law, we believe that flips per second can be continually improved in later technology generations of a wide class of probabilistic, domain specific hardware.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1907.09664/full.md

## Figures

38 figures with captions in the complete paper: https://tomesphere.com/paper/1907.09664/full.md

## References

81 references — full list in the complete paper: https://tomesphere.com/paper/1907.09664/full.md

---
Source: https://tomesphere.com/paper/1907.09664