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Main Authors: Casilli, Nicolas, Kaisar, Tahmid, Colombo, Luca, Ghosh, Siddhartha, Feng, Philip X. -L., Cassella, Cristian
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.08329
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author Casilli, Nicolas
Kaisar, Tahmid
Colombo, Luca
Ghosh, Siddhartha
Feng, Philip X. -L.
Cassella, Cristian
author_facet Casilli, Nicolas
Kaisar, Tahmid
Colombo, Luca
Ghosh, Siddhartha
Feng, Philip X. -L.
Cassella, Cristian
contents We report on a new class of Ising Machines (IMs) that rely on coupled parametric frequency dividers (PFDs) as macroscopic artificial spins. Unlike the IM counterparts based on subharmonic injection locking (SHIL), PFD IMs do not require strong injected continuous wave signals or applied DC voltages. Therefore, they show a significantly lower power consumption per spin compared to SHIL based IMs, making it feasible to accurately solve large scale combinatorial optimization problems (COPs) that are hard or even impossible to solve by using the current von Neumann computing architectures. Furthermore, using high quality (Q) factor resonators in the PFD design makes PFD IMs able to exhibit a nanoWatt level power per spin. Also, it remarkably allows a speed up of the phase synchronization among the PFDs, resulting in shorter time to solution and lower energy to solution despite the resonators' longer relaxation time. As a proof of concept, a 4 node PFD IM has been demonstrated. This IM correctly solves a set of MaxCut problems while consuming just 600 nanoWatts per spin. This power consumption is two orders of magnitude lower than the power per spin of state of the art SHIL based IMs operating at the same frequency.
format Preprint
id arxiv_https___arxiv_org_abs_2312_08329
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Parametric Frequency Divider based Ising Machines
Casilli, Nicolas
Kaisar, Tahmid
Colombo, Luca
Ghosh, Siddhartha
Feng, Philip X. -L.
Cassella, Cristian
Applied Physics
We report on a new class of Ising Machines (IMs) that rely on coupled parametric frequency dividers (PFDs) as macroscopic artificial spins. Unlike the IM counterparts based on subharmonic injection locking (SHIL), PFD IMs do not require strong injected continuous wave signals or applied DC voltages. Therefore, they show a significantly lower power consumption per spin compared to SHIL based IMs, making it feasible to accurately solve large scale combinatorial optimization problems (COPs) that are hard or even impossible to solve by using the current von Neumann computing architectures. Furthermore, using high quality (Q) factor resonators in the PFD design makes PFD IMs able to exhibit a nanoWatt level power per spin. Also, it remarkably allows a speed up of the phase synchronization among the PFDs, resulting in shorter time to solution and lower energy to solution despite the resonators' longer relaxation time. As a proof of concept, a 4 node PFD IM has been demonstrated. This IM correctly solves a set of MaxCut problems while consuming just 600 nanoWatts per spin. This power consumption is two orders of magnitude lower than the power per spin of state of the art SHIL based IMs operating at the same frequency.
title Parametric Frequency Divider based Ising Machines
topic Applied Physics
url https://arxiv.org/abs/2312.08329