Apers Simon, Chakraborty Shantanav, Novo Leonardo, Roland Jérémie
IRIF, CNRS, 75205 Paris, France.
CQST and CSTAR, International Institute of Information Technology Hyderabad, 500032 Telangana, India.
Phys Rev Lett. 2022 Oct 14;129(16):160502. doi: 10.1103/PhysRevLett.129.160502.
Continuous-time quantum walks provide a natural framework to tackle the fundamental problem of finding a node among a set of marked nodes in a graph, known as spatial search. Whether spatial search by continuous-time quantum walk provides a quadratic advantage over classical random walks has been an outstanding problem. Thus far, this advantage is obtained only for specific graphs or when a single node of the underlying graph is marked. In this Letter, we provide a new continuous-time quantum walk search algorithm that completely resolves this: our algorithm can find a marked node in any graph with any number of marked nodes, in a time that is quadratically faster than classical random walks. The overall algorithm is quite simple, requiring time evolution of the quantum walk Hamiltonian followed by a projective measurement. A key component of our algorithm is a purely analogue procedure to perform operations on a state of the form e^{-tH^{2}}|ψ⟩, which, for a given Hamiltonian H, only requires evolving H for time scaling as sqrt[t]. This allows us to quadratically fast-forward the dynamics of a continuous-time classical random walk. The applications of our Letter thus go beyond the realm of quantum walks and can lead to new analog quantum algorithms for preparing ground states of Hamiltonians or solving optimization problems.
连续时间量子游走提供了一个自然的框架,用于解决在图中一组标记节点中找到一个节点这一基本问题,即空间搜索。连续时间量子游走进行的空间搜索相较于经典随机游走是否具有二次方优势,一直是一个悬而未决的问题。到目前为止,仅在特定图或底层图的单个节点被标记时才能获得这种优势。在本信函中,我们提供了一种全新的连续时间量子游走搜索算法,彻底解决了这一问题:我们的算法能够在任意数量的标记节点的任何图中找到标记节点,其时间比经典随机游走快二次方倍。整个算法相当简单,需要对量子游走哈密顿量进行时间演化,随后进行投影测量。我们算法的一个关键组成部分是一个纯模拟过程,用于对形式为(e^{-tH^{2}}|\psi\rangle)的态执行操作,对于给定的哈密顿量(H),这仅要求将(H)演化时间按(\sqrt{t})进行缩放。这使我们能够以二次方速度快速推进连续时间经典随机游走的动力学。因此,我们信函的应用超出了量子游走的范畴,并且能够带来用于制备哈密顿量基态或解决优化问题的新的模拟量子算法。
