Bayesian optimization reliably identifies optimal protocols that maximize secret-key rates for heterogeneous quantum repeater chains with arbitrary nodes.
A quantum network of clocks
5 Pith papers cite this work. Polarity classification is still indexing.
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Proposes a heterogeneous quantum repeater network architecture using recursive designs and RuleSets with a new bridging building block, but states that full-scale resource trade-off analysis remains future work.
Arqon delivers reliable quantum network service via admission control and scheduling that satisfies defined reliability requirements for accepted demands in static topologies, with O(k^3) and O(N^3) complexity.
The authors introduce the LHD protocol for entanglement distribution under imperfect conditions and report via simulation that it outperforms some prior protocols against a blind entanglement baseline.
Quantum time synchronization protocols do not provide a near-term replacement for classical methods in most applications because time transfer precision remains the limiting factor, though they add value for physical-layer security.
citing papers explorer
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Bayesian Optimization for Repeater Protocols
Bayesian optimization reliably identifies optimal protocols that maximize secret-key rates for heterogeneous quantum repeater chains with arbitrary nodes.
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Resource Management in Heterogeneous Quantum Repeater Networks
Proposes a heterogeneous quantum repeater network architecture using recursive designs and RuleSets with a new bridging building block, but states that full-scale resource trade-off analysis remains future work.
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Arqon: A suite of control applications enabling a reliable quantum network
Arqon delivers reliable quantum network service via admission control and scheduling that satisfies defined reliability requirements for accepted demands in static topologies, with O(k^3) and O(N^3) complexity.
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Entanglement distribution protocols under imperfect fidelity and quantum memory conditions
The authors introduce the LHD protocol for entanglement distribution under imperfect conditions and report via simulation that it outperforms some prior protocols against a blind entanglement baseline.
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Quantum Protocols for Time Synchronisation and Distribution: A Critical Assessment
Quantum time synchronization protocols do not provide a near-term replacement for classical methods in most applications because time transfer precision remains the limiting factor, though they add value for physical-layer security.