Rydberg-Atom Graphs for Quadratic Unconstrained Binary Optimization Problems

IF 4.4 Q1 OPTICS Advanced quantum technologies Pub Date : 2024-06-19 DOI:10.1002/qute.202300398
Andrew Byun, Junwoo Jung, Kangheun Kim, Minhyuk Kim, Seokho Jeong, Heejeong Jeong, Jaewook Ahn
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Abstract

There is a growing interest in harnessing the potential of the Rydberg-atom system to address complex combinatorial optimization challenges. Here an experimental demonstration of how the quadratic unconstrained binary optimization (QUBO) problem can be effectively addressed using Rydberg-atom graphs is presented. The Rydberg-atom graphs are configurations of neutral atoms organized into mathematical graphs, facilitated by programmable optical tweezers, and designed to exhibit many-body ground states that correspond to the maximum independent set (MIS) of their respective graphs. Four elementary Rydberg-atom subgraph components are developed, not only to eliminate the need of local control but also to be robust against interatomic distance errors, while serving as the building blocks sufficient for formulating generic QUBO graphs. To validate the feasibility of the approach, a series of Rydberg-atom experiments selected to demonstrate proof-of-concept operations of these building blocks are conducted. These experiments illustrate how these components can be used to programmatically encode the QUBO problems to Rydberg-atom graphs and, by measuring their many-body ground states, how their QUBO solutions are determined subsequently.

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用于二次无约束二元优化问题的雷德堡原子图
利用 Rydberg-atom 系统的潜力来解决复杂的组合优化难题的兴趣与日俱增。这里介绍的是如何利用 Rydberg-atom 图形有效解决二次无约束二元优化(QUBO)问题的实验演示。雷德伯格原子图是由中性原子组成的数学图,由可编程光学镊子协助设计,旨在展示与其各自图的最大独立集(MIS)相对应的多体基态。我们开发了四个基本的雷德伯格原子子图组件,不仅消除了局部控制的需要,而且对原子间距离误差具有鲁棒性,同时可作为构成通用 QUBO 图的构件。为了验证该方法的可行性,我们进行了一系列雷德伯格原子实验,以演示这些构件的概念验证操作。这些实验说明了如何利用这些构件将 QUBO 问题程序化地编码为雷德伯格原子图,并通过测量它们的多体基态,随后确定它们的 QUBO 解。
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