TY - GEN
T1 - Testbed and Experiments for Quantum-Conventional Networking
AU - Rao, Nageswara S.V.
AU - Alshowkan, Muneer
AU - Chapman, Joseph C.
AU - Lu, Hsuan Hao
AU - Peters, Nicholas A.
AU - Lukens, Joseph M.
AU - Xue, Guoliang
AU - Guha, Saikat
AU - Van Milligen, Emily
AU - Towsley, Don
AU - Vardoyan, Gayane
AU - Bacciottini, Leonardo
AU - Fan, Linran
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The realization of quantum networks requires the development of devices and methods unprecedented in conventional networks, and yet they critically depend on the latter for implementing foundational blocks and essential operations. We describe a testbed to support the development and testing of their functionality and performance by providing quantum and conventional data planes and devices, together with a secure conventional control plane. It incorporates a variety of entangled photon sources, qubit technologies, detector technologies, photonic components, and supporting conventional switches and workstations. It implements a novel fiber telescoping scheme that provides suites of connections using fiber spools and inground-aerial fiber loops. We briefly summarize a variety of experiments conducted over this testbed including: (i) flex-grid quantum connection experiments, (ii) quantum state and channel tomography, (iii) utilization of quantum key distribution keys to secure conventional encryption and firewall devices, (iv) comparative study of analytical capacity estimates and entanglement throughput, (v) deployed squeezing coexisting with conventional communications, and (iv) measurement of polarization time variation.
AB - The realization of quantum networks requires the development of devices and methods unprecedented in conventional networks, and yet they critically depend on the latter for implementing foundational blocks and essential operations. We describe a testbed to support the development and testing of their functionality and performance by providing quantum and conventional data planes and devices, together with a secure conventional control plane. It incorporates a variety of entangled photon sources, qubit technologies, detector technologies, photonic components, and supporting conventional switches and workstations. It implements a novel fiber telescoping scheme that provides suites of connections using fiber spools and inground-aerial fiber loops. We briefly summarize a variety of experiments conducted over this testbed including: (i) flex-grid quantum connection experiments, (ii) quantum state and channel tomography, (iii) utilization of quantum key distribution keys to secure conventional encryption and firewall devices, (iv) comparative study of analytical capacity estimates and entanglement throughput, (v) deployed squeezing coexisting with conventional communications, and (iv) measurement of polarization time variation.
KW - coexistence
KW - entanglement distribution
KW - quantum-conventional testbed
KW - teleportation
UR - https://www.scopus.com/pages/publications/105007877289
UR - https://www.scopus.com/pages/publications/105007877289#tab=citedBy
U2 - 10.1109/QCNC64685.2025.00031
DO - 10.1109/QCNC64685.2025.00031
M3 - Conference contribution
AN - SCOPUS:105007877289
T3 - Proceedings - 2025 International Conference on Quantum Communications, Networking, and Computing, QCNC 2025
SP - 151
EP - 158
BT - Proceedings - 2025 International Conference on Quantum Communications, Networking, and Computing, QCNC 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2nd International Conference on Quantum Communications, Networking, and Computing, QCNC 2025
Y2 - 31 March 2025 through 2 April 2025
ER -