Add to ORKGSpatio-temporal control of femtosecond pulse-delivery through multimode fibers (MMF) can be used to achieve two photon photo-polymerization. Transmission-matrix method is used in linear domain to solve the scrambling effect at the fiber output and generate focused spots. However, multimode fibers suffer from non-linear effects at high peak intensities. The method is not effective to describe light propagation in the nonlinear regime. Here we propose a deep learning network which can learn the relationship between inputs and outputs of the MMF. We show that once the network is properly trained, it can directly calculate the inverse of the transmission matrix
We experimentally demonstrate the application of a double deep Q-learning network algorithm (DDQN) f...
International audienceWe show how neural networks can be used to model complex and predict nonlinear...
Image delivery through multimode fibers (MMFs) suffers from modal scrambling which results in a spec...
We propose a data -driven approach for light transmission control inside multimode fibers (MMFs). Sp...
Multimode fibers (MMFs) are an example of a highly scattering medium, which scramble the coherent li...
Multimode fibers (MMF) are remarkable high-capacity information channels. However, the MMF transmiss...
Multimode fibers (MMF) are high‐capacity channels and are promising to transmit spatially distribute...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
Multimode optical fibers (MMFs) have gained renewed interest in the past decade, emerging as a way t...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
Image transmission through a multi-mode fiber is a difficult task given the complex interference of ...
In this work, we present a method to characterise the transmission matrices of complex scattering me...
In this chapter, machine learning (ML) algorithm is introduced in single-step perturbation and multi...
We review our recent progress on the application of machine-learning techniques in the field of ultr...
We experimentally demonstrate the application of a double deep Q-learning network algorithm (DDQN) f...
International audienceWe show how neural networks can be used to model complex and predict nonlinear...
Image delivery through multimode fibers (MMFs) suffers from modal scrambling which results in a spec...
We propose a data -driven approach for light transmission control inside multimode fibers (MMFs). Sp...
Multimode fibers (MMFs) are an example of a highly scattering medium, which scramble the coherent li...
Multimode fibers (MMF) are remarkable high-capacity information channels. However, the MMF transmiss...
Multimode fibers (MMF) are high‐capacity channels and are promising to transmit spatially distribute...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
Multimode optical fibers (MMFs) have gained renewed interest in the past decade, emerging as a way t...
International audienceRecent years have seen the rapid growth of the field of smart photonics where ...
Image transmission through a multi-mode fiber is a difficult task given the complex interference of ...
In this work, we present a method to characterise the transmission matrices of complex scattering me...
In this chapter, machine learning (ML) algorithm is introduced in single-step perturbation and multi...
We review our recent progress on the application of machine-learning techniques in the field of ultr...
We experimentally demonstrate the application of a double deep Q-learning network algorithm (DDQN) f...
International audienceWe show how neural networks can be used to model complex and predict nonlinear...
Image delivery through multimode fibers (MMFs) suffers from modal scrambling which results in a spec...