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Quantum theory of temporally mismatched homodyne measurements with applications to optical-frequency-comb metrology

Noah Lordi, Eugene Tsao, Alexander J. Lind, Scott A. Diddams, Joshua Combes

2024Physical review. A/Physical review, A13 citationsDOIOpen Access PDF

Abstract

The fields of precision timekeeping and spectroscopy increasingly rely on optical-frequency-comb interferometry. However, comb-based measurements are not described by existing quantum theory because they exhibit both large mode mismatch and finite-strength local oscillators. To establish this quantum theory, we derive measurement operators for homodyne detection with arbitrary mode overlap. These operators are a combination of quadrature and intensity-like measurements, which inform a filter that maximizes the quadrature-measurement signal-to-noise ratio. Furthermore, these operators establish a foundation to extend frequency-comb interferometry to a wide range of scenarios, including metrology with nonclassical states of light.

Topics & Concepts

Quantum metrologyMetrologyDirect-conversion receiverFrequency combHomodyne detectionInterferometryPhysicsOpticsQuantum sensorQuantum opticsQuantumQuadrature (astronomy)Quantum mechanicsQuantum informationQuantum networkLaserAdvanced Fiber Laser TechnologiesPhotonic and Optical DevicesMechanical and Optical Resonators
Quantum theory of temporally mismatched homodyne measurements with applications to optical-frequency-comb metrology | Litcius