Numerical study using finite element method for the thermal response of fiber specklegram sensors with changes in the length of the sensing zone

Numerical study using finite element method for the thermal response of fiber specklegram sensors with changes in the length of the sensing zone

Автор: Arango Juan David, Vlez Yeraldin Alejandra, Aristizabal Victor Hugo, Vlez Francisco Javier, Gmez Jorge Alberto, Quijano Jairo Camilo, Herrera-Ramirez Jorge Alexis

Журнал: Компьютерная оптика @computer-optics

Рубрика: Дифракционная оптика, оптические технологии

Статья в выпуске: 4 т.45, 2021 года.

Бесплатный доступ

The response of fiber specklegram sensors (FSSs) is given as function of variations in the intensity distribution of the modal interference pattern or speckle pattern induced by external disturbances. In the present work, the behavior of a FSS sensing scheme under thermal perturbations is studied by means of computational simulations of the speckle patterns. These simulations are generated by applying the finite element method (FEM) to the modal interference in optical fibers as a function of the thermal disturbance and the length of the sensing zone. A correlation analysis is per-formed on the images generated in the simulations to evaluate the dependence between the changes in the speckle pattern grains and the intensity of the applied disturbance. The numerical simulation shows how the building characteristic of the length of sensing zone, combined with image processing, can be manipulated to control the metrological performance of the sensors.

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Fiber optics sensors, computational electromagnetic methods, numerical approximation and analysis, optical sensing and sensors, speckle interferometry

Короткий адрес: https://sciup.org/140290248

IDR: 140290248   |   DOI: 10.18287/2412-6179-CO-852

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