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Ultimate Spatial Resolution Realisation in Optical Frequency Domain Reflectometry with Equal Frequency Resampling

Zhen Guo, Gaoce Han, Jize Yan, David Greenwood, James Marco, Yifei Yu

2021Sensors45 citationsDOIOpen Access PDF

Abstract

A method based on equal frequency resampling is proposed to suppress laser nonlinear frequency sweeping for the ultimate spatial resolution in optical frequency domain reflectometry. Estimation inaccuracy of the sweeping frequency distribution caused by the finite sampling rate in the auxiliary interferometer can be efficiently compensated by the equal frequency resampling method. With the sweeping range of 130 nm, a 12.1 µm spatial resolution is experimentally obtained. In addition, the sampling limitation of the auxiliary interferometer-based correction is discussed. With a 200 m optical path delay in the auxiliary interferometer, a 21.3 µm spatial resolution is realised at the 191 m fibre end. By employing the proposed resampling and a drawing tower FBG array to enhance the Rayleigh backscattering, a distributed temperature sensing over a 105 m fibre with a sensing resolution of 1 cm is achieved. The measured temperature uncertainty is limited to ±0.15 °C.

Topics & Concepts

ReflectometryInterferometryOpticsResamplingImage resolutionSampling (signal processing)Frequency domainInterpolation (computer graphics)CalibrationSpatial frequencyResolution (logic)Materials sciencePhysicsComputer scienceTime domainTelecommunicationsAlgorithmFrame (networking)DetectorQuantum mechanicsComputer visionArtificial intelligenceAdvanced Fiber Optic SensorsOptical Coherence Tomography ApplicationsPhotonic and Optical Devices
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