High-dimensional encoding in entanglement-based QKD achieves optimal efficiency at finite photon pair production rates, boosting secret key rates by up to ten times compared to single-qubit approaches in low-signal satellite scenarios.
Aruteet al., Quantum supremacy using a programmable superconducting processor, Nature 574, 505 (2019)
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Quantum models show greater robustness and less accuracy degradation than classical models in low-data transfer learning regimes.
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Photon Efficiency of High-Dimensional Quantum Key Distribution
High-dimensional encoding in entanglement-based QKD achieves optimal efficiency at finite photon pair production rates, boosting secret key rates by up to ten times compared to single-qubit approaches in low-signal satellite scenarios.
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Quantum Transfer Learning Shows Improved Robustness in Low-Data Regimes
Quantum models show greater robustness and less accuracy degradation than classical models in low-data transfer learning regimes.