TY - JOUR
T1 - Experimental Demonstration of Datagram Switching With Monitoring in Quantum Wrapper Networks
AU - On, Mehmet Berkay
AU - Proietti, Roberto
AU - Gul, Gamze
AU - Kanter, Gregory S.
AU - Singh, Sandeep Kumar
AU - Kumar, Prem
AU - Yoo, S. J.Ben
N1 - Publisher Copyright:
© 1983-2012 IEEE.
PY - 2024/5/15
Y1 - 2024/5/15
N2 - Adapting the architecture and protocols of classical networks to quantum networking is challenging due to the quantum mechanical properties. In this article, we utilize a Quantum Wrapper Networking architecture that enables transparent and interoperable transportation of quantum wrapper (QW) datagrams, consisting of quantum payloads and classical headers, over optical fiber networks. We experimentally demonstrate end-to-end transportation of QW datagrams in a three-node packet-switched optical network testbed. The header and payload of a QW datagram are multiplexed in time and wavelength, i.e., the 1561.41 nm header precedes the L-band payload. A QW switch/router performs packet switching by reading the headers, generating new headers, and routing the datagrams to their destinations without disturbing quantum information in the payload. We use 20 km fiber links from the source to two distinct destinations in the testbed. Our experiments show >22 coincidence-to-accidental ratio (CAR) for both destinations at two different wavelength channels and clear visibility, >79%. We further investigate impairments such as chromatic dispersion and wavelength-dependent polarization rotations in the fiber. We observe that the classical headers' bit-error rate (BER) and the quantum payloads' CAR are correlated under the wavelength-independent channel attenuation. Thus, QW network control and management can utilize a type of performance monitoring. We also discuss the QW datagram design constraints and future fast packet switching implementations.
AB - Adapting the architecture and protocols of classical networks to quantum networking is challenging due to the quantum mechanical properties. In this article, we utilize a Quantum Wrapper Networking architecture that enables transparent and interoperable transportation of quantum wrapper (QW) datagrams, consisting of quantum payloads and classical headers, over optical fiber networks. We experimentally demonstrate end-to-end transportation of QW datagrams in a three-node packet-switched optical network testbed. The header and payload of a QW datagram are multiplexed in time and wavelength, i.e., the 1561.41 nm header precedes the L-band payload. A QW switch/router performs packet switching by reading the headers, generating new headers, and routing the datagrams to their destinations without disturbing quantum information in the payload. We use 20 km fiber links from the source to two distinct destinations in the testbed. Our experiments show >22 coincidence-to-accidental ratio (CAR) for both destinations at two different wavelength channels and clear visibility, >79%. We further investigate impairments such as chromatic dispersion and wavelength-dependent polarization rotations in the fiber. We observe that the classical headers' bit-error rate (BER) and the quantum payloads' CAR are correlated under the wavelength-independent channel attenuation. Thus, QW network control and management can utilize a type of performance monitoring. We also discuss the QW datagram design constraints and future fast packet switching implementations.
KW - Quantum networks
KW - packet switching
KW - quantum communication
KW - quantum-classical coexistence
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U2 - 10.1109/JLT.2024.3362292
DO - 10.1109/JLT.2024.3362292
M3 - Article
AN - SCOPUS:85184803508
SN - 0733-8724
VL - 42
SP - 3504
EP - 3514
JO - Journal of Lightwave Technology
JF - Journal of Lightwave Technology
IS - 10
ER -