Fiber Optic Temperature Sensor With Online Controllable Sensitivity Based on Vernier Effect

A highly-sensitive temperature sensor with controllable sensitivity based on Vernier effect by cascading a tunable extrinsic Fabry-Perot interferometer (FPI) and a fixed reflective Lyot filter (RLF) is theoretically investigated and experimentally demonstrated. The temperature sensitivity can be tuned by modulating the cavity length of the extrinsic FPI and online monitoring the envelope of superimposed spectrum with optical spectrum analyzer (OSA). The FPI works as the reference arm to tune the temperature sensitivity of the sensing system, while the RLF with 1-meter polarization maintaining fiber (PMF) acts as the sensing probe. Experimental results prove that by changing the cavity length of the FPI, the sensitivities of -3.82 nm/degrees C, -8.33 nm/degrees C and -14.63 nm/degrees C can be achieved. Compared with the single sensing element, the sensitivities are magnified by 3.78, 8.25 and 14.49 times. The proposed temperature sensor is feasible to be applied practically in scenarios which require different temperature sensitivities in demanded temperature detection ranges.

Automated summary

The highly-sensitive temperature sensor based on the Vernier effect utilizes a tunable extrinsic Fabry-Perot interferometer and a fixed reflective Lyot filter to achieve controllable sensitivity. By modulating the cavity length of the FPI, different temperature sensitivities can be achieved, magnifying the sensitivities compared to a single sensing element. The proposed sensor is feasible for practical applications requiring different temperature sensitivities in demanded temperature detection ranges.