Hyperspectral Image Spatial Super-Resolution via 3D Full Convolutional Neural Network
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TLDR
3D convolution is used to exploit both the spatial context of neighboring pixels and spectral correlation of neighboring bands, such that spectral distortion when directly applying traditional CNN based SR algorithms to hyperspectral images in band-wise manners is alleviated.Abstract:
Hyperspectral images are well-known for their fine spectral resolution to discriminate different materials. However, their spatial resolution is relatively low due to the trade-off in imaging sensor technologies, resulting in limitations in their applications. Inspired by recent achievements in convolutional neural network (CNN) based super-resolution (SR) for natural images, a novel three-dimensional full CNN (3D-FCNN) is constructed for spatial SR of hyperspectral images in this paper. Specifically, 3D convolution is used to exploit both the spatial context of neighboring pixels and spectral correlation of neighboring bands, such that spectral distortion when directly applying traditional CNN based SR algorithms to hyperspectral images in band-wise manners is alleviated. Furthermore, a sensor-specific mode is designed for the proposed 3D-FCNN such that none of the samples from the target scene are required for training. Fine-tuning by a small number of training samples from the target scene can further improve the performance of such a sensor-specific method. Extensive experimental results on four benchmark datasets from two well-known hyperspectral sensors, namely hyperspectral digital imagery collection experiment (HYDICE) and reflective optics system imaging spectrometer (ROSIS) sensors, demonstrate that our proposed 3D-FCNN outperforms several existing SR methods by ensuring higher quality both in reconstruction and spectral fidelity.read more
Citations
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Journal ArticleDOI
Deep Learning Meets Hyperspectral Image Analysis: A Multidisciplinary Review.
TL;DR: The present review is aimed at domain professionals who want to have an updated overview on how hyperspectral acquisition techniques can combine with deep learning architectures to solve specific tasks in different application fields and the machine learning and computer vision experts by giving them a picture of how deep learning technologies are applied to hyperspectrals data from a multidisciplinary perspective.
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Interpretable Hyperspectral Artificial Intelligence: When nonconvex modeling meets hyperspectral remote sensing
Danfeng Hong,Wei He,Naoto Yokoya,Jing Yao,Lianru Gao,Liangpei Zhang,Jocelyn Chanussot,Xiao Xiang Zhu +7 more
TL;DR: Compared to convex models, nonconvex modeling, which is capable of characterizing more complex real scenes and providing model interpretability technically and theoretically, has proven to be a feasible solution that reduces the gap between challenging HS vision tasks and currently advanced intelligent data processing models.
Journal ArticleDOI
A New Benchmark Based on Recent Advances in Multispectral Pansharpening: Revisiting Pansharpening With Classical and Emerging Pansharpening Methods
Gemine Vivone,Mauro Dalla Mura,Andrea Garzelli,Rocco Restaino,Giuseppe Scarpa,Magnus O. Ulfarsson,Luciano Alparone,Jocelyn Chanussot +7 more
TL;DR: A new benchmark consisting of recent advances in MS pansharpening is proposed, and optimized classical approaches [multiresolution analysis (MRA) and component substitution (CS)] are compared with methods belonging to the third generation of panshARPening, represented by variational optimization-based (VO) and machine learning (ML) techniques.
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Deep learning for land use and land cover classification based on hyperspectral and multispectral earth observation data: A review
TL;DR: This paper reviews the use of deep learning in land use and land cover classification based on multispectral and hyperspectral images and introduces the available data sources and datasets used by literature studies to provide the readers with a framework to interpret the-state-of-the-art ofdeep learning in this context.
Journal ArticleDOI
Hyperspectral Anomaly Detection by Fractional Fourier Entropy
TL;DR: Fractional Fourier entropy (FrFE)-based hyperspectral anomaly detection method can significantly distinguish signal from background and noise, and is implemented in the optimal fractional domain.
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