Digital holographic microscopy applied to 3D computer microvision by using deep neural networks

Jesús E. Brito Carcaño; Stéphane Cuenat; Belal Ahmad; Patrick Sandoz; Raphaël Couturier; Guillaume Laurent; Maxime Jacquot

doi:10.1051/epjconf/202328713011

All issues

Volume 287 (2023)

EPJ Web Conf., 287 (2023) 13011

Abstract

Open Access

Issue		EPJ Web Conf. Volume 287, 2023 EOS Annual Meeting (EOSAM 2023)


Article Number		13011
Number of page(s)		2
Section		Focused Sessions (FS) 4- Machine Learning and Photonic Artificial Intelligence / Optical Neural Networks and Neuromorphic Computing
DOI		https://doi.org/10.1051/epjconf/202328713011
Published online		18 October 2023

EPJ Web of Conferences 287, 13011 (2023)
https://doi.org/10.1051/epjconf/202328713011

Digital holographic microscopy applied to 3D computer microvision by using deep neural networks

Jesús E. Brito Carcaño^*, Stéphane Cuenat, Belal Ahmad, Patrick Sandoz, Raphaël Couturier, Guillaume Laurent and Maxime Jacquot

Université de Franche-Comté, SUPMICROTECH-ENSMM, CNRS, Institut FEMTO-ST, 1 rue Claude Goudimel, 25000 Besançon, France

^* Corresponding author: jesus.brito@femto-st.fr

Published online: 18 October 2023

Abstract

Deep neural networks are increasingly applied in many branches of applied science such as computer vision and image processing by increasing performances of instruments. Different deep architectures such as convolutional neural networks or Vision Transformers can be used in advanced coherent imaging techniques such as digital holography to extract various metrics such as autofocusing reconstruction distance or 3D position determination in order to target automated microscopy or real-time phase image restitution. Deep neural networks can be trained with both datasets simulated and experimental holograms, by transfer learning. Overall, the application of deep neural networks in digital holographic microscopy and 3D computer micro-vision has the potential to significantly improve the robustness and processing speed of holograms to infer and control a 3D position for applications in micro-robotics.

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