Abstract
Quantumnetworking is emerging as a new research area to explore the opportunities of interconnecting quantum systems through end-to-end entanglement of qubits at geographical distance via quantum repeaters. A promising architecture has been proposed in the literature that decouples entanglement between adjacent quantum nodes/repeaters from establishing end-to-end paths by adopting a time slotted approach. Within this model, we destructure further end-to-end path establishment into two subproblems: path selection and scheduling. The former is set to determine the best repeaters to connect two end nodes, provided that all their local entanglements have succeeded. On the other hand, scheduling is concerned with deciding, which pairs of end nodes are served in the current time slot, while the others remain queued for later time slots. Unlike path selection, scheduling has not been investigated so far in the literature, particularly in presence of quantum noise, which makes both problems even more challenging. In this article, we propose to address it via a general framework of heuristic algorithms, for which we propose three illustrative instances with the objective of keeping the application delay small while achieving a good system utilization, in terms of high entanglement rate and fidelity of remotely entangled qubits. The system proposed is evaluated extensively via event-driven quantum network simulations, with noisy repeaters, in different node topologies under a Poisson arrival of requests from quantum applications. The results show the existence of a fundamental tradeoff between system- and application-level metrics, such as fairness versus entanglement and fidelity, which lays the foundations for further studies in this thriving research area.
Highlights
Quantum computing is pushing the frontiers of computation and its advantages will be multiplied by the creation of a Quantum Internet to interconnect remote quantum computers with one another
Key difference: There is a fundamental difference between stochastic routing in Wireless Sensor Networkss (WSNs) and the quantum routing problem investigated in this work: as we will explain in more details in Sec
Unlike for grid topologies, even at the relatively low load of 1/λ = 1, there is a non-negligible fraction of node drops in which the entanglement rate is smaller than the offered load, despite the two topologies have the same number of nodes: this confirms that the topology can have a significant impact on performance
Summary
Quantum computing is pushing the frontiers of computation and its advantages will be multiplied by the creation of a Quantum Internet to interconnect remote quantum computers with one another. Short coherence times in quantum memories [7] These limitations create many research challenges for the realization of quantum networks based on entanglement swap. The controller tries to satisfy a set of demands from the upper layer applications by performing an ephemeral routing of multiple requests, which is only valid until the round of local link entanglements Whether this will be a practical setup for a quantum network, on a local or wide-area scale, only time will tell. II, and analyze one specific aspect that, to the best of our knowledge, has been overlooked in the studies so far: request scheduling The latter refers to the choice of which end-to-end entanglement requests to satisfy at any given time, based on the latest outcome of local entanglements, provided that it is not possible to grant immediately all the demands pending.
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