Multicore fiber-based quantum access network

TL;DR

This paper introduces a multicore fiber-based quantum access network that integrates quantum and classical signals, proposes a core and wavelength assignment scheme to reduce noise, and demonstrates its effectiveness through experiments supporting scalable quantum key distribution.

Contribution

It presents a novel multicore fiber architecture with a core and wavelength assignment scheme and experimental validation for scalable quantum key distribution networks.

Findings

CWAS reduces noise from SRS and crosstalk.

WTDM achieves higher SKR than TDM.

Experimental results confirm the effectiveness of the proposed scheme.

Abstract

We propose a quantum access network based on multicore fiber (MCF) to scale up the number of users in quantum key distribution (QKD) networks. The MCF is used as feeder fiber and single core single mode fibers (SSMFs) are used as drop fibers. Quantum signals (QSs) are integrated with classical signals (CSs) in both MCF and SSMFs to save deployment cost since access networks are cost sensitive. Due to the integration, spontaneous Raman scattering (SRS) and intercore crosstalk (ICXT) are the main impairment sources to QKD. To alleviate the noise, we propose a core and wavelength assignment scheme (CWAS) that a dedicated core of MCF is used to transmit QSs and the wavelengths of QSs are set lower than those of upstream signals. Also, we demonstrate that wavelength time division multiplexing (WTDM) is suitable for QSs which are required to support large number of quantum users, since WTDM can realize higher secure key rate (SKR) than time division multiplexing (TDM) and require lower cost than wavelength division multiplexing (WDM). Finally, the proposed quantum access network is verified experimentally. The experiment results are consistent with our analysis. The properties of SRS in the proposed architecture are shown in the experiments through the quantum bit error rates (QBERs) in different experimental case, which verifies the superiority of the proposed CWAS. Also, the characteristics of the SKRs prove that the number of receivers has a great impact on the performance of QSs using WTDM.