Your search keyword '"hyperspectral images (HSIs)"' showing total 25 results

1. Multiview Subspace Clustering of Hyperspectral Images Based on Graph Convolutional Networks

Author

Li, Xianju, Guan, Renxiang, Li, Zihao, Liu, Hao, Yang, Jing, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Song, Xiangyu, editor, Feng, Ruyi, editor, Chen, Yunliang, editor, Li, Jianxin, editor, and Min, Geyong, editor

Published

2024

2. Pseudolabeling Contrastive Learning for Semisupervised Hyperspectral and LiDAR Data Classification

Author

Zhongwei Li, Yuewen Wang, Leiquan Wang, Fangming Guo, Yajie Yang, and Jie Wei

Subjects

Contrastive learning, feature fusion, hyperspectral images (HSIs), light detection and ranging (LiDAR) data, remote sensing, Yellow River Delta, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Elevation information from light detection and ranging (LiDAR) data relieve the phenomenon of “same spectrum with different object” in hyperspectral images (HSI) classification. Consequently, HSI and LiDAR joint classification is a significant research topic. However, existing methods encounter several challenges. Primarily, there exists a deficiency in intraclass information interaction and underutilization of discriminative feature. Furthermore, the process of labeling samples is time-consuming and laborious. To solve the aforementioned issues, a classification method based on pseudolabeled contrastive learning is proposed to exploit substantial amounts of unlabeled information in order to enhance intraclass information interaction. The proposed method is divided into two stages for semisupervised classification. In the first stage, an unsupervised feature extraction network is designed to improve the interaction of features from multimodal data. A multimodal data cross-attention module is proposed to enhance the interaction of multimodal information at corresponding locations. Exploiting pseudolabeling contrastive learning module facilitates the interaction of information between intraclass objects. In the second stage, supervised classification with a limited number of labeled samples is performed. The multisource discriminatively consolidate feature module is designed to generate discriminative features, which are used to guide the fusion feature enhancement process. Apart from this, this module leverages multiscale features to expand the receptive field. Tested on both self-constructed and public datasets, the proposed method provides higher classification accuracy than some existing methods with a limited amount of labeled samples.

Published

2024

3. Shallow-Guided Transformer for Semantic Segmentation of Hyperspectral Remote Sensing Imagery.

Author

Chen, Yuhan, Liu, Pengyuan, Zhao, Jiechen, Huang, Kaijian, and Yan, Qingyun

Subjects

*TRANSFORMER models, *CONVOLUTIONAL neural networks, *HYPERSPECTRAL imaging systems, *REMOTE sensing

Abstract

Convolutional neural networks (CNNs) have achieved great progress in the classification of surface objects with hyperspectral data, but due to the limitations of convolutional operations, CNNs cannot effectively interact with contextual information. Transformer succeeds in solving this problem, and thus has been widely used to classify hyperspectral surface objects in recent years. However, the huge computational load of Transformer poses a challenge in hyperspectral semantic segmentation tasks. In addition, the use of single Transformer discards the local correlation, making it ineffective for remote sensing tasks with small datasets. Therefore, we propose a new Transformer layered architecture that combines Transformer with CNN, adopts a feature dimensionality reduction module and a Transformer-style CNN module to extract shallow features and construct texture constraints, and employs the original Transformer Encoder to extract deep features. Furthermore, we also designed a simple Decoder to process shallow spatial detail information and deep semantic features separately. Experimental results based on three publicly available hyperspectral datasets show that our proposed method has significant advantages compared with other traditional CNN, Transformer-type models. [ABSTRACT FROM AUTHOR]

Published

2023

4. An Attention-Enhanced Feature Fusion Network (AeF 2 N) for Hyperspectral Image Classification.

Author

Zheng, Yongjie, Liu, Sicong, and Bruzzone, Lorenzo

Abstract

In recent years, numerous deep learning (DL)-based frameworks have been proposed for hyperspectral image classification (HSIC). Considering a large number of spectral bands of hyperspectral images (HSIs), it is still challenging to effectively utilize the spectral information and achieve accurate classification when few training samples are available. To make full use of the spectral–spatial information in HSIs with few training samples, in this letter, we propose a lightweight end-to-end attention-enhanced feature fusion network (AeF2N). The proposed AeF2N consists of four sequential stages, i.e., spectral feature augmentation, spatial contextual feature interaction, spectral feature augmentation, and classification. The first and third stages are used to capture and augment the discriminative spectral features, while the second stage is used to capture spatial information. Notably, two novel attention blocks, spectral augmentation attention (SAA) and spatial integration attention (SIA) are interactively introduced to capture significant spectral and spatial information, respectively. Based on the proposed spectral and spatial feature discrimination stages, the AeF2N effectively identifies both spectrally significant (e.g., irregular small objects) and spatially significant (e.g., specific-shaped objects) land objects with high accuracy. Experimental results obtained on three benchmark hyperspectral datasets demonstrate the superiority of the proposed approach compared with six state-of-the-art DL-based methods in terms of higher classification accuracy and efficiency. [ABSTRACT FROM AUTHOR]

Published

2023

5. SFFGL: A Semantic Feature Fused Global Learning Framework for Multiclass Change Detection in Hyperspectral Images.

Author

Wang, Lifeng, Zhang, Junguo, Wang, Liguo, and Bruzzone, Lorenzo

Abstract

Deep learning techniques have shown increasing potential in change detection (CD) in hyperspectral images (HSIs). However, most deep learning-based existing methods for HSI CD follow a patch-based local learning framework and concentrate on binary CD. In this letter, we propose an end-to-end semantic feature fused global learning (SFFGL) framework for HSI multiclass CD (MCD). In SFFGL, a global spatialwise fully convolutional network (FCN), which introduces a spatial attention mechanism (PAM) between encoder and decoder, is designed to effectively exploit the global spatial information from the whole HSIs and achieve patch-free inference. PAM can adaptively extract global spatialwise feature representation. In the model training stage, a global hierarchical (GH) sampling strategy is introduced to obtain diverse gradients during backpropagation for more robust performance. The semantic–spatial feature fusion ($\text{S}^{2}\text{F}^{2}$) unit is designed to effectively fuse the enhanced spatial context information in the encoder and the semantic information in the decoder. More importantly, a semantic feature enhancement module (SEM) is proposed to weaken the influence of the unchanged regional background on the change regional foreground, thus further improving the accuracy. Experimental results on two benchmark HSI datasets demonstrate the effectiveness of the proposed SFFGL. [ABSTRACT FROM AUTHOR]

Published

2023

6. Subfeature Ensemble-Based Hyperspectral Anomaly Detection Algorithm

Author

Shuo Wang, Wei Feng, Yinghui Quan, Wenxing Bao, Gabriel Dauphin, Lianru Gao, Xian Zhong, and Mengdao Xing

Subjects

Anomaly detection, hyperspectral images (HSIs), feature ensemble, unsupervised object detection, remote sensing, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral images (HSIs) have always played an important role in remote sensing applications. Anomaly detection has become a hot spot in HSI processing in recent years. The popular detecting method is to accurately segment anomalies from the background. Informative bands are very important for the accuracy improvement of the detection technology. However, most of the abnormal targets segmentation methods focus on the usage of all the spectral features, thus are easily affected by redundant bands or feature noise. A hyperspectral anomaly detection algorithm based on subfeature ensemble is proposed in this article. The proposed method consists of the following steps. First, the bands of the original HSI are normalized and randomly divided into several subfeature sets according to different proportions. Second, six methods including the prior-based tensor approximation algorithm (PTA), Reed–Xiaoli method, a low-rank and sparse representation method, a low-rank and sparse matrix decomposition-based Mahalanobis distance method, the graph and total variation regularized low-rank representation-based method, and a method based on tensor principal component analysis are applied to detect anomalies on the original HSI, and the method with the best performance is used to obtain an enhanced feature set. Then, the enhanced features and the subfeatures are ensembled iteratively to construct a new dataset. Finally, the PTA method is operated on the dataset with ensemble features to get the final abnormal target results. Six hyperspectral datasets are used in the experiment. Seven methods are employed as comparisons. The results are analyzed from both qualitative and quantitative perspectives. Extensive experimental results illustrate that the proposed method performs best on all datasets.

Published

2022

7. SPCNet: A Subpixel Convolution-Based Change Detection Network for Hyperspectral Images With Different Spatial Resolutions.

Author

Wang, Lifeng, Wang, Liguo, Wang, Heng, Wang, Xiaoyi, and Bruzzone, Lorenzo

Subjects

*SPATIAL resolution, *PIXELS, *FEATURE extraction, *DEEP learning

Abstract

The very high spectral resolution in hyperspectral images (HSIs) offers an opportunity to detect subtle land-cover changes. However, the availability of HSIs acquired from different platforms requires the development of change detection (CD) methods capable of processing HSIs with different spatial resolutions. In this article, we propose a general end-to-end subpixel convolution-based residual network (SPCNet) to accomplish the CD task between high spatial resolution (HR) and low spatial resolution (LR) HSIs. To effectively tackle the resolution matching issue, a super-resolution (SR) block with an efficient subpixel convolution layer is introduced to upscale the LR feature maps into HR maps. The subpixel convolution layer can fully explore the subpixel context information by learning an array of upscaling filters. Moreover, the designed SPC module is embedded into the LR branch to generate more discriminative representations. More importantly, the SPC module as a plug-and-play unit has the potential to be embedded into other baseline networks to enhance the feature learning capability. Experimental results on four HSI datasets demonstrate the effectiveness of the proposed SPCNet. [ABSTRACT FROM AUTHOR]

Published

2022

8. RSCNet: A Residual Self-Calibrated Network for Hyperspectral Image Change Detection.

Author

Wang, Liguo, Wang, Lifeng, Wang, Qunming, and Bruzzone, Lorenzo

Subjects

*CONVOLUTIONAL neural networks, *DEEP learning

Abstract

Deep learning-based methods (e.g., convolutional neural network (CNN)-based methods) have shown increasing potential in hyperspectral image (HSI) change detection (CD). However, the recent advances in CNN-based methods in HSI CD tasks are mostly devoted to designing more complex architectures or adding additional hand-designed blocks. This increases the number of parameters making model training difficult. In this article, we propose an end-to-end residual self-calibrated network (RSCNet) to increase the accuracy of HSI CD. To fully exploit the spatial information, the proposed RSCNet method adaptively builds interspatial and interspectral dependencies around each spatial location with fewer extra parameters and reduced complexity. Moreover, the introduced self-calibrated convolution (SCConv) helps to generate more discriminative representations by heterogeneously exploiting convolutional filters nested in the convolutional layer. The designed RSC module can explicitly incorporate richer information by introducing response calibration operation. The experiments on four bitemporal HSI datasets demonstrated that the proposed RSCNet method is more accurate than ten widely used benchmark methods. [ABSTRACT FROM AUTHOR]

Published

2022

9. Hyperspectral Image Stripe Removal Network With Cross-Frequency Feature Interaction.

Author

Wang, Chengjun, Xu, Miaozhong, Jiang, Yonghua, Deng, Guohui, Lu, Zhongyuan, Zhang, Guo, and Cui, Hao

Subjects

*RANDOM noise theory, *CONVOLUTIONAL neural networks, *STRIPES, *REMOTE sensing, *IMAGE processing, *IMAGE denoising

Abstract

Remote sensing images, especially hyperspectral images (HSIs), are extremely vulnerable to random noise and stripe noise. As a key aspect of HSI data quality improvement, stripe noise removal has always been a pervasive issue in remote sensing image processing. Convolutional neural networks have been applied for HSI data destriping. However, the existing methods lose the stripe-free component of the original image to a certain extent. These models also ignore the global spatial context of images and the correlation between spatial information and spectral information. Therefore, we propose a novel destriping convolutional network to overcome the problems with the existing methods. Octave convolution is used to extract cross-frequency features, and separate and compress the low-frequency information of the images, while dilation convolution (Dila-Conv) is used to reduce the amount of required calculation and also preserve the key image information. In addition, Dila-Conv can expand the receptive field to obtain multiscale features. Finally, a cross-channel enhanced spatial–spectral feature fusion module is used to acquire and integrate spatial context information and interchannel dependencies on a global scale as auxiliary information so that the network model can learn and pay attention to key feature information, specifically, “what to look for” and “where to look at,” which can facilitate the distinction between stripe and stripe-free components. Experimental results obtained using multiple datasets demonstrated that the proposed method can outperform the existing comparable methods and can produce satisfactory results in terms of visual effects and quantitative evaluation. [ABSTRACT FROM AUTHOR]

Published

2022

10. Dual-Branch Difference Amplification Graph Convolutional Network for Hyperspectral Image Change Detection.

Author

Qu, Jiahui, Xu, Yunshuang, Dong, Wenqian, Li, Yunsong, and Du, Qian

Subjects

*CONVOLUTIONAL neural networks, *CONVOLUTION codes, *REMOTE sensing, *DEEP learning, *ELECTRONIC data processing

Abstract

Hyperspectral image (HSI) change detection aims to identify the differences in multitemporal HSIs. Recently, a graph convolutional network (GCN) has attracted increasing attention in the field of remote sensing due to its advantages in processing irregular data. In comparison with a convolutional neural network (CNN) that can only perform convolution operations on data with the assumption of the Euclidean structure, GCN adopts a graph structure to flexibly capture the characteristics and structure information of non-Euclidean data. In this article, we propose a novel dual-branch difference amplification GCN (D2AGCN) for HSI change detection with limited samples, which allows the network to fully extract and effectively amplify the difference features of multitemporal HSIs for change detection. The dual-branch structure can effectively extract sufficient different features to facilitate the detection of the changed areas. As far as we know, this is the first time that GCN has been introduced into HSI change detection. A difference magnification module is designed to suppress similar regions and highlight the feature differences between the multitemporal HSIs in the dual-branch structure, which increases the distinction between change and nonchange classes. The visual and quantitative experimental results on three real hyperspectral datasets (i.e., China, Bay Area, and Santa Barbara) show that the proposed D2AGCN outperforms most of the state-of-the-art methods in HSI change detection with limited training samples. [ABSTRACT FROM AUTHOR]

Published

2022

11. Supervoxel-Based Intrinsic Scene Properties From Hyperspectral Images and LiDAR.

Author

Jin, Xudong, Gu, Yanfeng, Liu, Tianzhu, and Xie, Wen

Subjects

*OPTICAL radar, *LIDAR, *REMOTE sensing, *SURFACE geometry, *SURFACE emitting lasers, *POINT cloud, *PIXELS, *OPTICAL scanners

Abstract

The combination of spectral and 3-D elevation information provided by hyperspectral images (HSIs) and Light Detection and Ranging (LiDAR) has gained increased attention in the remote sensing field and enabled numerous applications. While various methods have been proposed to fuse these two data streams in pixel, feature, or decision level, a deeper view into the intrinsic relation of surface geometry, material reflectance, and environment illumination is still lacking. In this article, we present a novel supervoxel-based joint intrinsic decomposition framework for HSIs and LiDAR. First, we proposed a novel intrinsic scene model for HSIs and LiDAR point cloud, which tells how we can map LiDAR point cloud into HSI pixels with point-cloud-level normals, reflectance, and incident light direction. Then, we extract supervoxels from the LiDAR point cloud using a graph-based supervoxel method. Finally, we formulate the intrinsic decomposition problem within a supervoxel-based framework which can be optimized effectively and efficiently. The outputs of the proposed model are intrinsic scene properties like incident light direction and point-cloud-level hyperspectral reflectance, with which we can then generate intrinsic hyperspectral point cloud (IHSPC) where each point possesses not only 3-D coordinates and normals but also the reflectance over each wavelength. The performance of our approach is demonstrated with both synthetic and real data. [ABSTRACT FROM AUTHOR]

Published

2022

12. Kernel-Based Nonlinear Anomaly Detection via Union Dictionary for Hyperspectral Images.

Author

Gao, Yenan, Gu, Jiafeng, Cheng, Tongkai, and Wang, Bin

Subjects

*ANOMALY detection (Computer security), *INTRUSION detection systems (Computer security), *HYPERSPECTRAL imaging systems, *REMOTE sensing, *DETECTORS

Abstract

Anomaly detection has been known to be an important issue in hyperspectral remote sensing applications. It aims to detect anomalous targets whose spectral signatures are very different from the background pixels. Although many linear detectors have obtained acceptable detection results, the linear model might not be able to describe complex hyperspectral data and could be replaced by nonlinear models. In this article, we investigate the intrinsic nonlinear characteristics of hyperspectral images (HSIs) on basis of the nonlinear mixing models and propose a novel nonlinear hyperspectral anomaly detection method based on kernel theory and union dictionary. First, the global strong anomalies in the scene and the local background pixels are utilized to construct a union dictionary. Then, a nonlinear representation-based anomaly detection model with the constructed union dictionary is designed, in which the nonlinear mixing effect of HSIs is considered. Meanwhile, the kernel theory is exploited to deal with the nonlinear interactions among the atoms in the dictionary. Finally, the anomalous level of a test pixel is determined by the representation coefficients associated with the anomaly dictionary. The proposed method is evaluated on both synthetic and real hyperspectral datasets. Experimental results demonstrate its excellent performance in comparison with linear and nonlinear state-of-the-art anomaly detectors. [ABSTRACT FROM AUTHOR]

Published

2022

13. Hyperspectral Anomaly Detection for Spectral Anomaly Targets via Spatial and Spectral Constraints.

Author

Li, Zhuang, Zhang, Ye, and Zhang, Junping

Subjects

*ANOMALY detection (Computer security), *FALSE alarms, *INTRUSION detection systems (Computer security), *HEISENBERG uncertainty principle, *REMOTE sensing, *DETECTION alarms, *FOURIER transforms

Abstract

Anomaly detection in a hyperspectral image (HSI) has been actively researched in the field of remote sensing due to its significant application requirements. Traditional methods were based on the spatial models for the background to detect the anomaly targets. However, in detecting the spectral anomaly targets, they led to two problems: 1) the spatial characteristics of spectral anomaly targets are not obvious, which causes many false alarms in detection and 2) spectral anomaly usually occurs in the local band of targets, while the rest of the spectrum is similar to the ones of surrounding backgrounds, which leads to missed detection. This article proposes a novel hyperspectral anomaly detection method for spectral anomaly targets based on spatial and spectral constraints (SASCs). This model finds suspected anomaly target part as spatial anomaly results through SASCs. Then, the feedback process determines the spectral anomaly through the spectral difference between the tested pixel and the surrounding background. It is fed back to the spatial anomaly results to obtain final detection results. Furthermore, in order to enlarge the spectral difference between anomaly and background while suppressing the background, the optimal order of fractional Fourier transform (FrFT) is determined by combining spatial anomaly results with the uncertainty principle, which is used in FrFT of HSI. Experimental results show that the proposed method suppresses the background and reduces the false alarm rate. The feedback mechanism effectively reduces the missing detection rate, achieving a promising detection accuracy. [ABSTRACT FROM AUTHOR]

Published

2022

14. Structure Aware Generative Adversarial Networks for Hyperspectral Image Classification

Author

Tayeb Alipour-Fard and Hossein Arefi

Subjects

Deep learning (DL), hyperspectral images (HSIs), convolutional neural network (CNN), generative adversarial networks (GANs), remote sensing, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Generative adversarial networks (GANs) have shown striking performances in computer vision applications to augment virtual training samples (VTS). However, the VTS generating by GANs in the context of hyperspectral image classification suffer from structural inconsistency due to the insufficient number of training samples in order to learn high-order features from the discriminator. This work addresses the scarcity of training samples by designing a GAN, in which the performance of discriminator is improved to produce more structurally coherent VTS. In the proposed method, by splitting the discriminator into two parts, GAN undertakes two tasks: the main task is to learn to distinguish between real and fake samples, and the auxiliary task is to learn to distinguish structurally corrupted and real samples. With this setup, GAN will produce real-like VTS with a higher variation than conventional GAN. Furthermore, in order to reduce the computational cost, subspace-based dimension reduction was performed to obtain the dominant features around the training samples to generate meaningful patterns from the original ones to be used in the learning phase. Based on the experimental results on real, and well-known hyperspectral benchmark images, the proposed method improves the performance compared with GANs-related, and conventional data augmentation strategies1.

Published

2020

15. Regularization Parameter Selection in Minimum Volume Hyperspectral Unmixing.

Author

Zhuang, Lina, Lin, Chia-Hsiang, Figueiredo, Mario A. T., and Bioucas-Dias, Jose M.

Subjects

*REMOTE sensing, *MATHEMATICAL regularization, *MACHINE learning, *NONSMOOTH optimization

Abstract

Linear hyperspectral unmixing (HU) aims at factoring the observation matrix into an endmember matrix and an abundance matrix. Linear HU via variational minimum volume (MV) regularization has recently received considerable attention in the remote sensing and machine learning areas, mainly owing to its robustness against the absence of pure pixels. We put some popular linear HU formulations under a unifying framework, which involves a data-fitting term and an MV-based regularization term, and collectively solve it via a nonconvex optimization. As the former and the latter terms tend, respectively, to expand (reducing the data-fitting errors) and to shrink the simplex enclosing the measured spectra, it is critical to strike a balance between those two terms. To the best of our knowledge, the existing methods find such balance by tuning a regularization parameter manually, which has little value in unsupervised scenarios. In this paper, we aim at selecting the regularization parameter automatically by exploiting the fact that a too large parameter overshrinks the volume of the simplex defined by the endmembers, making many data points be left outside of the simplex and hence inducing a large data-fitting error, while a sufficiently small parameter yields a large simplex making data-fitting error very small. Roughly speaking, the transition point happens when the simplex still encloses the data cloud but there are data points on all its facets. These observations are systematically formulated to find the transition point that, in turn, yields a good parameter. The competitiveness of the proposed selection criterion is illustrated with simulated and real data. [ABSTRACT FROM AUTHOR]

Published

2019

16. Unsupervised Cross-Temporal Classification of Hyperspectral Images With Multiple Geodesic Flow Kernel Learning.

Author

Liu, Tianzhu, Zhang, Xiangrong, and Gu, Yanfeng

Subjects

*GEODESIC flows, *CLASSIFICATION, *REMOTE sensing

Abstract

With the increasing acquisition ability of hyperspectral remote sensing images, unsupervised cross-temporal classification (UCTC) of hyperspectral images (HSIs) has attracted more and more attention. In this paper, we focus on cross-temporal HSI classification, i.e., using one labeled HSI to classify the other unlabeled HSI. A multiple geodesic flow kernel learning (MGFKL) framework is proposed to exploit both spatial and spectral features for UCTC with bitemporal HSIs and called S2-MGFKL. The proposed S2-MGFKL method first extracts extended multi-attribute profiles (EMAPs) from the original bitemporal HSIs. The spatial features of the bitemporal HSIs obtained by the same attribute filter are paired up, so are the original spectral features. Second, each pair of features from both source and target domains are used to construct multiple geodesic flows. According to the original definition of GFK, we can obtain the construction of Gaussian base GFKs. The base kernels consist of two parts, the spectral part is obtained base on the same geodesic flow (which is constructed on the bitemporal spectral features) by tuning the kernel scale, while the spatial part is obtained under the same kernel scale but different geodesic flows constructed on different spatial feature pairs. After that, the mean rule is adopted to acquire the combined kernel, which is fed into the supervised vector machine (SVM) to implement the cross-temporal classification task. Experiments are conducted on two real HSI data sets, and the results compared with several well-known methods demonstrate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

17. Hyperspectral Anomaly Detection via Background and Potential Anomaly Dictionaries Construction.

Author

Huyan, Ning, Zhang, Xiangrong, Zhou, Huiyu, and Jiao, Licheng

Subjects

*HYPERSPECTRAL imaging systems, *ANOMALY detection (Computer security), *REMOTE sensing, *MACHINE learning, *DATA analysis

Abstract

In this paper, we propose a new anomaly detection method for hyperspectral images based on two well-designed dictionaries: background dictionary and potential anomaly dictionary. In order to effectively detect an anomaly and eliminate the influence of noise, the original image is decomposed into three components: background, anomalies, and noise. In this way, the anomaly detection task is regarded as a problem of matrix decomposition. Considering the homogeneity of background and the sparsity of anomalies, the low-rank and sparse constraints are imposed in our model. Then, the background and potential anomaly dictionaries are constructed using the background and anomaly priors. For the background dictionary, a joint sparse representation (JSR)-based dictionary selection strategy is proposed, assuming that the frequently used atoms in the overcomplete dictionary tend to be the background. In order to make full use of the prior information of anomalies hidden in the scene, the potential anomaly dictionary is constructed. We define a criterion, i.e., the anomalous level of a pixel, by using the residual calculated in the JSR model within its local region. Then, it is combined with a weighted term to alleviate the influence of noise and background. Experiments show that our proposed anomaly detection method based on potential anomaly and background dictionaries construction can achieve superior results compared with other state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2019

18. Hyperspectral Imaging and Applications.

Author

Chang, Chein-I, Chang, Chein-I, Song, Meiping, Wu, Chao-Cheng, and Zhang, Junping

Subjects

History of engineering & technology, Technology: general issues, 90° yaw imaging, AHS, AVIRIS, Africa, Dunhuang site, Gram-Schmidt orthogonalization, HyMap, KSVD, Otsu's method, SVM, adaptive window, agroforestry, airborne laser scanning, algebraic multigrid methods, anomaly detection, band expansion process (BEP), band grouping, band selection, band selection (BS), band subset selection (BSS), biodiversity, class imbalance, classification, composite kernel, constrained energy minimization, constrained energy minimization (CEM), correlation band expansion process (CBEP), data fusion, data integration, data unmixing, data-guided constraints, deep belief networks, deep learning, deep pipelined background statistics, endmember extraction, ensemble learning, evenness, fire severity, graph, hashing ensemble, hierarchical feature, high-level synthesis, hyperspectral, hyperspectral classification, hyperspectral compression, hyperspectral detection, hyperspectral image, hyperspectral image (HSI), hyperspectral image classification, hyperspectral imagery, hyperspectral images (HSIs), hyperspectral imaging, hyperspectral pansharpening, hyperspectral unmixing, image enhancement, image fusion, imaging spectroscopy, in situ measurements, intrinsic image decomposition, irradiance-based method, iterative CEM (ICEM), iterative algorithm, label propagation, linearly constrained minimum variance (LCMV), local abundance, local summation RX detector (LS-RXD), lossy compression, machine learning, mineral mapping, minimum noise fraction, multiscale spatial information, multiscale union regions adaptive sparse representation (MURASR), nonlinear band expansion (NBE), nonnegative matrix factorization, nuclear norm, on-board compression, optical spectral region, orthogonal projections, panchromatic, panchromatic image, parallel processing, peatland, progressive sample processing (PSP), prototype space, raw material, real-time processing, recursive anomaly detection, reflectance-based method, remote sensing, rolling guidance filtering (RGF), rotation forest, semi-supervised learning, semi-supervised local discriminant analysis, sequential LCMV-BSS (SQ LCMV-BSS), sliding window, sparse coding, sparse unmixing, sparseness, spectral mixture analysis, spectral variability, spectral-spatial classification, sprout detection, structure tensor, successive LCMV-BSS (SC LCMV-BSS), superpixel, target detection, terrestrial hyperspectral imaging, texture feature enhancement, thermal infrared spectral region, tree species, tree-based ensemble, vegetation type, vicarious calibration, vineyard, water stress, weighted fusion, weighted least squares filter

Abstract

Summary: Due to advent of sensor technology, hyperspectral imaging has become an emerging technology in remote sensing. Many problems, which cannot be resolved by multispectral imaging, can now be solved by hyperspectral imaging. The aim of this Special Issue "Hyperspectral Imaging and Applications" is to publish new ideas and technologies to facilitate the utility of hyperspectral imaging in data exploitation and to further explore its potential in different applications. This Special Issue has accepted and published 25 papers in various areas, which can be organized into 7 categories with the number of papers published in every category included in its open parenthesis. 1. Data Unmixing (2 papers)2. Spectral variability (2 papers)3. Target Detection (3 papers)4. Hyperspectral Image Classification (6 papers)5. Band Selection (2 papers)6. Data Fusion (2 papers)7. Applications (8 papers) Under every category each paper is briefly summarized by a short description so that readers can quickly grab its content to find what they are interested in.

19. Joint Reconstruction and Anomaly Detection From Compressive Hyperspectral Images Using Mahalanobis Distance-Regularized Tensor RPCA.

Author

Xu, Yang, Wu, Zebin, Wei, Zhihui, and Chanussot, Jocelyn

Subjects

*ANOMALY detection (Computer security), *SPECTRAL imaging, *MULTIPLE correspondence analysis (Statistics), *REMOTE sensing, *ELECTROMAGNETIC waves

Abstract

Anomaly detection plays an important role in remotely sensed hyperspectral image (HSI) processing. Recently, compressive sensing technology has been widely used in hyperspectral imaging. However, the reconstruction from compressive HSI and detection are commonly completed independently, which will reduce the processing’s efficiency and accuracy. In this paper, we propose a framework for hyperspectral compressive sensing with anomaly detection which reconstruct the HSI and detect the anomalies simultaneously. In the proposed method, the HSI is composed of the background and anomaly parts in the tensor robust principal component analysis model. To characterize the low-dimensional structure of the background, a novel tensor nuclear norm is used to constrain the background tensor. As the anomaly part is formed by a few anomalous spectra, the anomaly part is assumed to be a tuber-wise sparse tensor. In addition, to enhance the separation of the background and anomaly, we minimize the sum of Mahalanobis distance of the background pixels. Experiments on four HSIs demonstrate that the proposed method outperforms several state-of-the-art methods on both reconstruction and anomaly detection accuracies. [ABSTRACT FROM AUTHOR]

Published

2018

20. Multimorphological Superpixel Model for Hyperspectral Image Classification.

Author

Tianzhu Liu, Yanfeng Gu, Chanussot, Jocelyn, and Dalla Mura, Mauro

Subjects

*HYPERSPECTRAL imaging systems, *REMOTE sensing, *PIXELS, *SUPPORT vector machines, *CLUSTER analysis (Statistics)

Abstract

With the development of hyperspectral sensors, nowadays, we can easily acquire large amount of hyperspectral images (HSIs) with very high spatial resolution, which has led to a better identification of relatively small structures. Owing to the high spatial resolution, there are much less mixed pixels in the HSIs, and the boundaries between these categories are much clearer. However, the high spatial resolution also leads to complex and fine geometrical structures and high inner-class variability, which make the classification results very “noisy.” In this paper, we propose a multimorphological superpixel (MMSP) method to extract the spectral and spatial features and address the aforementioned problems. To reduce the difference within the same class and obtain multilevel spatial information, morphological features (multistructuring element extended morphological profile or multiattribute filter extended multi-attribute profiles) are first obtained from the original HSI. After that, simple linear iterative clustering segmentation method is performed on each morphological feature to acquire the MMSPs. Then, uniformity constraint is used to merge the MMSPs belonging to the same class which can avoid introducing the information from different classes and acquire spatial structures at object level. Subsequently, mean filtering is utilized to extract the spatial features within and among MMSPs. At last, base kernels are obtained from the spatial features and original HSI, and several multiple kernel learning methods are used to obtain the optimal kernel to incorporate into the support vector machine. Experiments conducted on three widely used real HSIs and compared with several well-known methods demonstrate the effectiveness of the proposed model. [ABSTRACT FROM PUBLISHER]

Published

2017

21. Multiple Kernel Learning for Hyperspectral Image Classification: A Review.

Author

Gu, Yanfeng, Chanussot, Jocelyn, Jia, Xiuping, and Benediktsson, Jon Atli

Subjects

*HYPERSPECTRAL imaging systems, *SPECTRAL imaging, *REMOTE sensing, *DATA structures, *KERNEL (Mathematics)

Abstract

With the rapid development of spectral imaging techniques, classification of hyperspectral images (HSIs) has attracted great attention in various applications such as land survey and resource monitoring in the field of remote sensing. A key challenge in HSI classification is how to explore effective approaches to fully use the spatial–spectral information provided by the data cube. Multiple kernel learning (MKL) has been successfully applied to HSI classification due to its capacity to handle heterogeneous fusion of both spectral and spatial features. This approach can generate an adaptive kernel as an optimally weighted sum of a few fixed kernels to model a nonlinear data structure. In this way, the difficulty of kernel selection and the limitation of a fixed kernel can be alleviated. Various MKL algorithms have been developed in recent years, such as the general MKL, the subspace MKL, the nonlinear MKL, the sparse MKL, and the ensemble MKL. The goal of this paper is to provide a systematic review of MKL methods, which have been applied to HSI classification. We also analyze and evaluate different MKL algorithms and their respective characteristics in different cases of HSI classification cases. Finally, we discuss the future direction and trends of research in this area. [ABSTRACT FROM PUBLISHER]

Published

2017

22. Hyperspectral and Multispectral Image Fusion Based on Local Low Rank and Coupled Spectral Unmixing.

Author

Zhou, Yuan, Feng, Liyang, Hou, Chunping, and Kung, Sun-Yuan

Subjects

*HYPERSPECTRAL imaging systems, *MULTISPECTRAL imaging, *IMAGE fusion, *REMOTE sensing, *SPATIAL systems

Abstract

Hyperspectral images (HSIs) usually have high spectral and low spatial resolution. Conversely, multispectral images (MSIs) usually have low spectral and high spatial resolution. The fusion of HSI and MSI aims to create spectral images with high spectral and spatial resolution. In this paper, we propose a fusion algorithm by combining linear spectral unmixing with the local low-rank property. By taking advantage of the local low-rank property, we first partition the corresponding spectral image into patches. For each patch pair, we cast the fusion problem as a coupled spectral unmixing problem that extracts the abundance and the endmembers of MSI and HSI, respectively. It then updates the abundance and the endmember through an alternating update algorithm. In fact, the convergence of the alternative update algorithm can be mathematically and empirically supported. We also propose a multiscale postprocessing procedure to combine fusion results obtained under different patch sizes. In experiments on three data sets, the proposed fusion algorithms outperformed state-of-the-art fusion algorithms in both spatial and spectral domains. [ABSTRACT FROM PUBLISHER]

Published

2017

23. Hybrid-hypergraph regularized multiview subspace clustering for hyperspectral images

Author

Hongyan Zhang, Shaoguang Huang, and Aleksandra Pizurica

Subjects

Hypergraph, Image segmentation, Technology and Engineering, Clustering algorithms, Hyperspectral imaging, Computer science, business.industry, Pattern recognition, subspace clustering, remote sensing, Subspace clustering, Sparse matrices, multiview clustering, General Earth and Planetary Sciences, Feature extraction, Artificial intelligence, Electrical and Electronic Engineering, Clustering methods, business, Hyperspectral images (HSIs), Erbium

Abstract

Clustering algorithms play an essential and unique role in classification tasks, especially when annotated data are unavailable or very scarce. Current clustering approaches in remote sensing are mostly designed for a single data source, such as hyperspectral image (HSI), while, nowadays, multisensor data are being routinely acquired. In this article, we propose a multiview subspace clustering model that exploits effectively the rich information from multiple features extracted either from a single data source (HSI) or from multiple sources that we call generically multiviews of the same scene. An important novelty of our approach is that it integrates local and nonlocal spatial information from each view in a unified framework. Our model learns a common intrinsic cluster structure from view-specific subspace representations by a new decomposition-based scheme. In addition, we develop innovative manifold-based spatial regularization as a hybrid hypergraph, which merges local and nonlocal spatial context and improves, thereby, the learning of view-specific structures. We develop an efficient algorithm to solve the resulting optimization problem. Extensive experiments on real data sets demonstrate the superior clustering performance over the state of the art.

Published

2022

24. Adaptable Convolutional Network for Hyperspectral Image Classification.

Author

Paoletti, Mercedes E. and Haut, Juan M.

Subjects

*HYPERSPECTRAL imaging systems, *CONVOLUTIONAL neural networks, *DEEP learning, *REMOTE sensing, *CLASSIFICATION

Abstract

Nowadays, a large number of remote sensing instruments are providing a massive amount of data within the frame of different Earth Observation missions. These instruments are characterized by the wide variety of data they can collect, as well as the impressive volume of data and the speed at which it is acquired. In this sense, hyperspectral imaging data has certain properties that make it difficult to process, such as its large spectral dimension coupled with problematic data variability. To overcome these challenges, convolutional neural networks have been proposed as classification models because of their ability to extract relevant spectral–spatial features and learn hidden patterns, along their great architectural flexibility. Their high performance relies on the convolution kernels to exploit the spatial relationships. Thus, filter design is crucial for the correct performance of models. Nevertheless, hyperspectral data may contain objects with different shapes and orientations, preventing filters from "seeing everything possible" during the decision making. To overcome this limitation, this paper proposes a novel adaptable convolution model based on deforming kernels combined with deforming convolution layers to fit their effective receptive field to the input data. The proposed adaptable convolutional network (named DKDCNet) has been evaluated over two well-known hyperspectral scenes, demonstrating that it is able to achieve better results than traditional strategies with similar computational cost for HSI classification. [ABSTRACT FROM AUTHOR]

Published

2021

25. Deep&Dense Convolutional Neural Network for Hyperspectral Image Classification.

Author

Paoletti, Mercedes E., Haut, Juan M., Plaza, Javier, and Plaza, Antonio

Subjects

*HYPERSPECTRAL imaging systems, *DEEP learning, *REMOTE sensing, *SIGNAL convolution

Abstract

Deep neural networks (DNNs) have emerged as a relevant tool for the classification of remotely sensed hyperspectral images (HSIs), with convolutional neural networks (CNNs) being the current state-of-the-art in many classification tasks. However, deep CNNs present several limitations in the context of HSI supervised classification. Although deep models are able to extract better and more abstract features, the number of parameters that must be fine-tuned requires a large amount of training data (using small learning rates) in order to avoid the overfitting and vanishing gradient problems. The acquisition of labeled data is expensive and time-consuming, and small learning rates forces the gradient descent to use many small steps to converge, slowing down the runtime of the model. To mitigate these issues, this paper introduces a new deep CNN framework for spectral-spatial classification of HSIs. Our newly proposed framework introduces shortcut connections between layers, in which the feature maps of inferior layers are used as inputs of the current layer, feeding its own output to the rest of the the upper layers. This leads to the combination of various spectral-spatial features across layers that allows us to enhance the generalization ability of the network with HSIs. Our experimental results with four well-known HSI datasets reveal that the proposed deep&dense CNN model is able to provide competitive advantages in terms of classification accuracy when compared to other state-of-the-methods for HSI classification. [ABSTRACT FROM AUTHOR]

Published

2018