核心概念
The paper proposes an efficient entanglement routing scheme for satellite-aerial-terrestrial quantum networks to maximize quantum network throughput by jointly optimizing path selection and entanglement generation rates.
要約
The paper investigates the collaboration among satellite, aerial, and terrestrial quantum networks to efficiently transmit high-fidelity quantum entanglements over long distances. It begins with a comprehensive overview of existing satellite-, aerial-, and terrestrial-based quantum networks.
The authors then address the entanglement routing problem with the objective of maximizing quantum network throughput by jointly optimizing path selection and entanglement generation rates (PS-EGR). The original problem is formulated as a mixed-integer linear programming (MILP) problem, which is inherently intractable. To solve the problem efficiently, the authors propose a Benders' decomposition (BD)-based algorithm.
The numerical results validate the effectiveness of the proposed PS-EGR scheme, offering valuable insights into various optimizable factors within the system. Finally, the paper discusses the current challenges and proposes promising avenues for future research in satellite-aerial-terrestrial quantum networks.
統計
In the considered SATQN, the average EPR pair generation rate between adjacent nodes in free space (including S2S, S2A, A2A, S2G, and A2G links) is randomly selected from the range [200, 1400] EGR pairs, while the rate for adjacent nodes in G2G links is randomly selected from the range [400, 1600] EGR pairs.
The storage capacity of each storage node is set to 1500 EPR pairs.
The link fidelity is randomly chosen from [0.96, 0.99].
引用
"To facilitate long-distance quantum entanglement distribution, quantum repeaters equipped with quantum memories are incorporated into the communication link. These repeaters perform entanglement swapping and purification, thereby ensuring high-quality end-to-end user entanglements."
"By integrating both satellite- and aerial-based quantum networks with terrestrial-based quantum networks, the satellite-aerial-terrestrial quantum network (SATQN) offers a comprehensive and versatile solution to tackle diverse communication challenges and paves the way for the upcoming 6G network and beyond."