Add to ORKGWe propose a deep learning based method to estimate high-resolution images from multiple fiber bundle images. Our approach first aligns raw fiber bundle image sequences with a motion estimation neural network and then applies a 3D convolution neural network to learn a mapping from aligned fiber bundle image sequences to their ground truth images. Evaluations on lens tissue samples and a 1951 USAF resolution target suggest that our proposed method can significantly improve spatial resolution for fiber bundle imaging systems. (C) 2019 Optical Society of America under the terms of the OSA Open Access Publishing Agreemen
A relatively new research field of neurosciences, called Connectomics, aims to achieve a full unders...
Abstract Multimode fibers (MMFs) have the potential to carry complex images for endoscopy and relate...
We demonstrate that images can be reconstructed for objects away from the imaging plane without any ...
We propose a deep learning based method to estimate high-resolution images from multiple fiber bundl...
Fiber bundle imaging systems use a bundle of single coherent fiber cores as imaging probe to capture...
We propose a deep learning-based restoration method to remove honeycomb patterns and improve resolut...
As the representative of flexibility in optical imaging media, in recent years, fiber bundles have e...
Image transmission through a multi-mode fiber is a difficult task given the complex interference of ...
We demonstrate a fully flexible, artifact-free, and lensless fiber-based imaging system. For the fir...
We demonstrate for the first time that deep neural networks (DNNs) can be trained to recover images ...
Image delivery through multimode fibers (MMFs) suffers from modal scrambling which results in a spec...
A multimode fiber represents the ultimate limit in miniaturization of imaging endoscopes. Here we pr...
We demonstrate a bending-independent imaging system for the first time by combining deep neural netw...
Training a neural network to reconstruct images from time-series waveforms obtained from fiber optic...
We propose a data -driven approach for light transmission control inside multimode fibers (MMFs). Sp...
A relatively new research field of neurosciences, called Connectomics, aims to achieve a full unders...
Abstract Multimode fibers (MMFs) have the potential to carry complex images for endoscopy and relate...
We demonstrate that images can be reconstructed for objects away from the imaging plane without any ...
We propose a deep learning based method to estimate high-resolution images from multiple fiber bundl...
Fiber bundle imaging systems use a bundle of single coherent fiber cores as imaging probe to capture...
We propose a deep learning-based restoration method to remove honeycomb patterns and improve resolut...
As the representative of flexibility in optical imaging media, in recent years, fiber bundles have e...
Image transmission through a multi-mode fiber is a difficult task given the complex interference of ...
We demonstrate a fully flexible, artifact-free, and lensless fiber-based imaging system. For the fir...
We demonstrate for the first time that deep neural networks (DNNs) can be trained to recover images ...
Image delivery through multimode fibers (MMFs) suffers from modal scrambling which results in a spec...
A multimode fiber represents the ultimate limit in miniaturization of imaging endoscopes. Here we pr...
We demonstrate a bending-independent imaging system for the first time by combining deep neural netw...
Training a neural network to reconstruct images from time-series waveforms obtained from fiber optic...
We propose a data -driven approach for light transmission control inside multimode fibers (MMFs). Sp...
A relatively new research field of neurosciences, called Connectomics, aims to achieve a full unders...
Abstract Multimode fibers (MMFs) have the potential to carry complex images for endoscopy and relate...
We demonstrate that images can be reconstructed for objects away from the imaging plane without any ...