Abstract
We study a quantum entanglement switch that serves $k$ users in a star topology. We model variants of the system using Markov chains and standard queueing theory and obtain expressions for switch capacity and the expected number of qubits stored in memory at the switch. While it is more accurate to use a discrete-time Markov chain (DTMC) to model such systems, we quickly encounter practical constraints of using this technique and switch to using continuous-time Markov chains (CTMCs). Using CTMCs allows us to obtain a number of analytic results for systems in which the links are homogeneous or heterogeneous and for switches that have infinite or finite buffer sizes. In addition, we can model the effects of decoherence of quantum states fairly easily using CTMCs. We also compare the results we obtain from the DTMC against the CTMC in the case of homogeneous links and infinite buffer, and learn that the CTMC is a reasonable approximation of the DTMC. From numerical observations, we discover that decoherence has little effect on capacity and expected number of stored qubits for homogeneous systems. For heterogeneous systems, especially those operating close to stability constraints, buffer size and decoherence can have significant effects on performance metrics. We also learn that in general, increasing the buffer size from one to two qubits per link is advantageous to most systems, while increasing the buffer size further yields diminishing returns.
Highlights
Entanglement is an essential component of quantum computation, information, and communication
We study in detail the most basic and fundamental component of a quantum network—a single quantum switch that serves k users in a star topology
The cutoff time has slightly varying definitions in different contexts: in some cases, it is viewed as a quantum memory lifetime, and determines how long a qubit should be held in memory, as the effects of decoherence on the quantum state are considered too great beyond the cutoff time
Summary
Entanglement is an essential component of quantum computation, information, and communication. Throughout this article, we refer to these pairs of stored qubits as stored entanglements Another factor that impacts performance is decoherence of quantum states and subsequent qubit storage cutoff times that may be imposed by the switch or an application to prevent the consumption of low-fidelity states; we model this and study its effect. We derive in closed-form the distribution of the number of stored qubits at the switch Both C and E[Q] depend on the values of k, n, entanglement generation and decoherence rates, number of quantum memories (often referred to as buffer size throughout this article), and the switching mechanism, including the scheduling policy used by the switch.
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