Design and Simulation of the Adaptive Continuous Entanglement Generation Protocol

TL;DR

This paper introduces the Adaptive Continuous Entanglement Generation Protocol (ACP) for quantum networks, which continuously generates and adaptively manages entanglement to significantly reduce distribution time and improve fidelity.

Contribution

The paper proposes a novel adaptive protocol for continuous entanglement generation and extends a simulator to evaluate its performance in quantum networks.

Findings

ACP reduces time-to-serve by up to 94%

ACP increases entanglement fidelity by up to 0.05

Simulation results validate the protocol's effectiveness

Abstract

Generating and distributing remote entangled pairs (EPs) is a primary function of quantum networks, as entanglement is the fundamental resource for key quantum network applications. A critical performance metric for quantum networks is the time-to-serve (TTS) for users' EP requests, which is the time to distribute EPs between the requested nodes. Minimizing the TTS is essential given the limited qubit coherence time. In this paper, we study the Adaptive Continuous entanglement generation Protocol (ACP), which enables quantum network nodes to continuously generate EPs with their neighbors, while adaptively selecting the neighbors to optimize TTS. Meanwhile, entanglement purification is used to mitigate decoherence in pre-generated EPs prior to the arrival of user requests. We extend the SeQUeNCe simulator to fully implement ACP and conduct extensive simulations across various network scales. Our results show that ACP reduces TTS by up to 94% and increases entanglement fidelity by up to 0.05.