Quantum Time Transfer: A Practical Method for Lossy and Noisy Channels
Randy Lafler, R. Nicholas Lanning
Abstract
Precise clock synchronization is important for quantum networking, enhanced position, navigation, timing, and other applications that require clock synchronization better than GPS, but remains an ongoing challenge. The authors propose a solution using hardware native to quantum networking. This quantum-time-transfer technique can quickly achieve picosecond-level clock synchronization despite relatively low-performance quantum-photon sources and detection equipment. Furthermore, it is robust against the high loss and high noise channel conditions representative of daytime space-Earth links, and could provide high-precision secure timing in GPS-denied environments.
Topics & Concepts
Time transferComputer scienceClock synchronizationLossy compressionGlobal Positioning SystemSynchronization (alternating current)QuantumReal-time computingElectronic engineeringChannel (broadcasting)PhysicsComputer networkTelecommunicationsEngineeringQuantum mechanicsArtificial intelligenceAdvanced Frequency and Time StandardsQuantum optics and atomic interactionsAtomic and Subatomic Physics Research