Rendezvous is an old problem of assuring that two or more parties, initially separated, not knowing the position of each other, and not allowed to communicate, meet without pre-agreement on the meeting point. This problem has been extensively studied in classical computer science and has vivid importance to modern applications like coordinating a fleet of drones in an enemy's territory. Quantum non-locality, like Bell inequality violation, has shown that in many cases quantum entanglement allows for improved coordination of two separated parties compared to classical sources. The non-signaling correlations in many cases even strengthened such phenomena. In this work, we analyze, how Bell non-locality can be used by asymmetric location-aware agents trying to rendezvous on a finite network with a limited number of steps. We provide the optimal solution to this problem for both agents using quantum resources, and agents with only ``classical'' computing power. Our results show that for cubic graphs and cycles it is possible to gain an advantage by allowing the agents to use assistance of entangled quantum states.
翻译:共和性是一个老问题,即确保两个或两个以上当事方(最初是分开的,不知道对方的立场,也不允许相互沟通)在没有就会议点达成事先协议的情况下会面。这个问题在古典计算机科学中已经进行了广泛的研究,对现代应用具有生动的重要性,比如在敌人的领土上协调无人驾驶飞机队。像Bell的不平等侵犯一样,量子缠绕表明,在许多情况下,量子缠绕可以使两个分离的当事方与古典来源加强协调。许多情况下的非发件关系甚至加强了这种现象。在这项工作中,我们分析的是,不对称地点觉察剂如何利用贝尔的非地点性,试图在一个有限的网络上聚集,采取有限的步骤。我们为使用量子资源的代理人和仅具有“古典”计算能力的代理人提供了解决这一问题的最佳办法。我们的结果显示,对于三次图表和循环而言,允许代理人使用混合量子状态的协助是有可能获得好处的。