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Quantum-Enhanced Fiber-Optic Gyroscopes Using Quadrature Squeezing and Continuous-Variable Entanglement

Michael R. Grace, Christos N. Gagatsos, Quntao Zhuang, Saikat Guha

2020Physical Review Applied40 citationsDOIOpen Access PDF

Abstract

We evaluate the fundamental performance of a fiber-optic gyroscope (FOG) design that is enhanced by the injection of a quantum-optical squeezed vacuum. In the presence of fiber loss, we compute the optimum attainable enhancement below the standard quantum limit in terms of the angular velocity estimator variance from a homodyne measurement. We find that currently realizable amounts of single-mode squeezing are sufficient to access the maximum quantitative improvement, but that this gain in maximum rotation sensitivity is limited to a marginal constant factor. We then propose an entanglement-enhanced FOG design that segments a fixed amount of available fiber into multiple fiber interferometers and feeds this sensor array with a multimode-entangled squeezed vacuum resource. Our design raises the fundamental improvement in sensitivity to an appreciable factor of $e\ensuremath{\approx}2.718$.

Topics & Concepts

GyroscopePhysicsHomodyne detectionRing laser gyroscopeAstronomical interferometerFibre optic gyroscopeSensitivity (control systems)Quantum entanglementEstimatorQuadrature (astronomy)Angular velocityOpticsRotation (mathematics)Limit (mathematics)Quantum mechanicsQuantumQuantum limitDirect-conversion receiverSqueezed coherent stateQuantum noiseOptical fiberAllan varianceFiberConstant (computer programming)Sagnac effectNoise (video)Mechanical and Optical ResonatorsQuantum Information and CryptographyPulsars and Gravitational Waves Research