TY - GEN
T1 - Entangled Pair Resource Allocation Under Uncertain Fidelity Requirements
AU - Kaewpuang, Rakpong
AU - Xu, Minrui
AU - Turner, Stephen John
AU - Niyato, Dusit
AU - Yu, Han
AU - Kim, Dong In
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - In quantum networks, effective entanglement routing facilitates remote entanglement communication between quantum source and quantum destination nodes. Unlike routing in classical networks, entanglement routing in quantum networks must consider the quality of entanglement qubits (i.e., entanglement fidelity), presenting a challenge in ensuring entanglement fidelity over extended distances. To address this issue, we propose a resource allocation model for entangled pairs and an entanglement routing model with a fidelity guarantee. This approach jointly optimizes entangled resources (i.e., entangled pairs) and entanglement routing to support applications in quantum networks. Our proposed model is formulated using two-stage stochastic programming, taking into account the uncertainty of quantum application requirements. Aiming to minimize the total cost, our model ensures efficient utilization of entangled pairs and energy conservation for quantum repeaters under uncertain fidelity requirements. Experimental results demonstrate that our proposed model can reduce the total cost by at least 20% compared to the baseline model.
AB - In quantum networks, effective entanglement routing facilitates remote entanglement communication between quantum source and quantum destination nodes. Unlike routing in classical networks, entanglement routing in quantum networks must consider the quality of entanglement qubits (i.e., entanglement fidelity), presenting a challenge in ensuring entanglement fidelity over extended distances. To address this issue, we propose a resource allocation model for entangled pairs and an entanglement routing model with a fidelity guarantee. This approach jointly optimizes entangled resources (i.e., entangled pairs) and entanglement routing to support applications in quantum networks. Our proposed model is formulated using two-stage stochastic programming, taking into account the uncertainty of quantum application requirements. Aiming to minimize the total cost, our model ensures efficient utilization of entangled pairs and energy conservation for quantum repeaters under uncertain fidelity requirements. Experimental results demonstrate that our proposed model can reduce the total cost by at least 20% compared to the baseline model.
KW - end-to-end fidelity
KW - entangled pair resource allocation
KW - entanglement purification
KW - entanglement routing
KW - Quantum networks
KW - stochastic programming
UR - https://www.scopus.com/pages/publications/85166342349
U2 - 10.1109/BSC57238.2023.10201812
DO - 10.1109/BSC57238.2023.10201812
M3 - Conference contribution
AN - SCOPUS:85166342349
T3 - 2023 Biennial Symposium on Communications, BSC 2023
SP - 25
EP - 30
BT - 2023 Biennial Symposium on Communications, BSC 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2023 Biennial Symposium on Communications, BSC 2023
Y2 - 4 July 2023 through 7 July 2023
ER -