Comparative performance evaluation of classical methods and a deep learning approach for temperature prediction in fiber optic specklegram sensors

• Published in: Kompʹûternaâ optika Vol. 48; no. 5; pp. 689 - 695
• Main Authors: Vélez, F.J., Arango, J.D., Aristizábal, V.H., Trujillo, C.A., Herrera-Ramírez, J.
• Format: Journal Article
• Language: English
• Published: Samara National Research University 01.10.2024
• Subjects: convolutional neural network; deep learning; fiber specklegram sensors; finite element method; interrogation methods
• ISSN: 0134-2452; 2412-6179
• DOI: 10.18287/2412-6179-CO-1467

In this study, an algorithm based on convolutional neural networks is employed as an interrogation method for a fiber specklegram sensor. This algorithm is compared with conventional interrogation methods, including correlation between images, measurement of optical power, and radial moments. Fiber specklegram sensors have room for improvement as conventional methods only consider a single characteristic of the specklegram for variable prediction, thus failing to leverage the full spectrum of information within the specklegram. Consequently, the approach put forth here introduces a convolutional neural network for the extraction of specklegram features, accompanied by an artificial neural network for variable regression. The specklegrams used in this investigation are obtained through simulating temperature disturbances in a multimode fiber using the Finite Elements Method. The results reveal prediction RMSE errors ranging from 10.26°C for the first radial moment to 1.42°C for the proposed algorithm. These findings underscore the effectiveness of the proposed strategy in enhancing sensor performance and robustness, all while upholding their cost-efficiency.