Pico-strain-level dynamic perturbation measurement using {\pi}FBG sensor

TL;DR

This paper introduces a novel interferometric method for pico-strain-level dynamic perturbation measurement using { extpi}FBG sensors, leveraging optical filtering to enable high sensitivity detection of weak dynamic strains.

Contribution

The study proposes a simple, innovative approach to interrogate { extpi}FBG sensors with interferometry by optical filtering, enabling longer path differences and higher sensitivity in strain measurements.

Findings

Achieves high-resolution dynamic strain measurement down to 4 p{ extepsilon}/sqrt(Hz)

Enables longer interferometer path differences due to narrow transmission notch

Demonstrates theoretical feasibility of pico-strain detection with { extpi}FBG sensors

Abstract

Interferometric interrogation technique realized for conventional fiber Bragg grating (FBG) sensors is historically known to offer the highest sensitivity measurements, however, it has not been yet explored for {\pi}-phase-shifted FBG ({\pi}FBG) sensors. This, we believe, is due to the complex nature of the reflection/transmission spectrum of a {\pi}FBG, which cannot be directly used for interferometric interrogation purpose. Therefore, we propose here an innovative as well as simple concept towards this direction, wherein, the transmission spectrum of a {\pi}FBG sensor is optically filtered using a specially designed fiber grating. The resulting filtered spectrum retains the entire characteristics of a {\pi}FBG sensor and hence the filtered spectrum can be interrogated with interferometric principles. Furthermore, due to the extremely narrow transmission notch of a {\pi}FBG sensor, a fiber interferometer can be realized with significantly longer path difference. This leads to substantially enhanced detection limit as compared to sensors based on a regular FBG of similar length. Theoretical analysis demonstrate that high resolution weak dynamic strain measurement down to 4 p{\epsilon}/sqrt(Hz) is easily achievable.