Your search keyword '"hyperspectral images (HSIs)"' showing total 249 results

1. Fast Spectral Clustering via Efficient Multilayer Anchor Graph.

Author

Wei, Yiwei, Niu, Chao, Liu, Dejun, Ren, Peinan, and Liu, Chuang

Subjects

*TIME complexity, *PRINCIPAL components analysis

Abstract

Recent studies have shown that graph‐based clustering methods are good at processing hyperspectral images (HSIs), while falling short for large‐scale HSIs due to high time complexity. Meanwhile, the performance of these methods relies on the quality of the constructed graph with selected anchor points. More anchor points bring better clustering results for graph‐based methods. Time complexity, however, sees a considerable increase as the number of anchor points grows. Therefore, a method that can obtain efficient clustering accuracy and consumes less time is to be developed. Against this backdrop, a novel algorithm named fast spectral clustering via efficient multilayer anchor graph (FEMAG) is proposed to resolve the accuracy and time‐consuming trade‐off problem. First, FEMAG adopts superpixel principal component analysis (SuperPCA) to extract the low‐dimensional features of HSIs. Then, a multilayer anchor graph is constructed to improve the clustering performance. When constructing the similarity graph, FEMAG takes balanced K‐means‐based hierarchical K‐means (BKHK) to obtain outperforming anchor points efficiently. Extensive experiments validate that FEMAG achieves better clustering accuracy while taking less time compared to previous clustering methods. [ABSTRACT FROM AUTHOR]

Published

2024

2. Advanced Hyperspectral Image Analysis: Superpixelwise Multiscale Adaptive T-HOSVD for 3D Feature Extraction.

Author

Dai, Qiansen, Ma, Chencong, and Zhang, Qizhong

Subjects

*IMAGE analysis, *CALCULUS of tensors, *IMAGE recognition (Computer vision), *DATA distribution

Abstract

Hyperspectral images (HSIs) possess an inherent three-order structure, prompting increased interest in extracting 3D features. Tensor analysis and low-rank representations, notably truncated higher-order SVD (T-HOSVD), have gained prominence for this purpose. However, determining the optimal order and addressing sensitivity to changes in data distribution remain challenging. To tackle these issues, this paper introduces an unsupervised Superpixelwise Multiscale Adaptive T-HOSVD (SmaT-HOSVD) method. Leveraging superpixel segmentation, the algorithm identifies homogeneous regions, facilitating the extraction of local features to enhance spatial contextual information within the image. Subsequently, T-HOSVD is adaptively applied to the obtained superpixel blocks for feature extraction and fusion across different scales. SmaT-HOSVD harnesses superpixel blocks and low-rank representations to extract 3D features, effectively capturing both spectral and spatial information of HSIs. By integrating optimal-rank estimation and multiscale fusion strategies, it acquires more comprehensive low-rank information and mitigates sensitivity to data variations. Notably, when trained on subsets comprising 2%, 1%, and 1% of the Indian Pines, University of Pavia, and Salinas datasets, respectively, SmaT-HOSVD achieves impressive overall accuracies of 93.31%, 97.21%, and 99.25%, while maintaining excellent efficiency. Future research will explore SmaT-HOSVD's applicability in deep-sea HSI classification and pursue additional avenues for advancing the field. [ABSTRACT FROM AUTHOR]

Published

2024

3. 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

4. Hyperspectral Image Super-Resolution: Task-Based Evaluation

Author

Michal Kawulok, Pawel Kowaleczko, Maciej Ziaja, Jakub Nalepa, Daniel Kostrzewa, Daniele Latini, Davide De Santis, Giorgia Salvucci, Ilaria Petracca, Valeria La Pegna, Zoltan Bartalis, and Fabio Del Frate

Subjects

Hyperspectral images (HSIs), spatial resolution, spectral consistency, super-resolution (SR), task-based evaluation, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

The need for enhancing image spatial resolution has motivated the researchers to propose numerous super-resolution (SR) techniques, including those developed specifically for hyperspectral data. Despite significant advancements in this field attributed to deep learning, little attention has been given to evaluating the practical value of super-resolved images in specific applications. Most methods are validated in application-independent scenarios, often using simulated low-resolution images, resulting in overly optimistic conclusions. In this article, we propose task-based evaluation strategies for hyperspectral image SR and we present results obtained with various approaches that include pansharpening, multispectral–hyperspectral data fusion, and single-image SR. We demonstrate that the proposed framework allows us to highlight both benefits and limitations of each method and can, therefore, guide the development of SR techniques suitable for real-world applications.

Published

2024

5. UMTF-Net: An Unsupervised Multiscale Transformer Fusion Network for Hyperspectral and Multispectral Image Fusion

Author

Shuaiqi Liu, Shichong Zhang, Siyuan Liu, Bing Li, and Yu-Dong Zhang

Subjects

Hyperspectral images (HSIs), image fusion, transformer, U-network (U-Net), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral images (HSIs) are extensively utilized in several fields due to their abundant spectral band, particularly for tasks like ground object classification and environmental monitoring. However, as a result of equipment and imaging condition constraints, HSI frequently demonstrates a restricted spatial resolution. The fusion of a low-resolution HSI and a high-resolution multispectral image (HR-MSI) of the same scene is a crucial method for generating an HR-HSI. At present, due to factors, such as complexity and GPU memory limitation, most of the HSI–MSI fusion algorithms based on deep learning (DL) cannot utilize the transformer module well to capture the long-range dependence information in large-size remote sensing images. At the same time, the lack of a large amount of high-quality training data has become an important problem that affects the performance of fusion algorithms based on DL. In response to the above issues, this article introduces a new unsupervised multiscale transformer fusion (UMTF) network, called UMTF-Net, which enables HSI–MSI fusion without the need for additional training data. UMTF-Net is composed of an HSI fusion network and a U-network (U-Net)-based multiscale feature extraction network. In order to learn the cross-feature spatial similarity and long-range dependency of MSI and HSI, we first extract the multiscale features of MSI using the U-Net-based multiscale feature extraction network. We then input these features into the corresponding scale cross-feature fusion transformer module in the HSI fusion network to conduct feature fusion. Then, we input the fused features into the spatial spectral fuse attention module for spatial spectral feature enhancement, and finally generate HR-HSI. Comparing UMTF-Net to other advanced methods, the fusion results from three datasets and multiple ablation experiments indicate that our method performs excellently in different evaluations.

Published

2024

6. 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

7. Hyperspectral Anomaly Detection via Merging Total Variation Into Low-Rank Representation

Author

Linwei Li, Ziyu Wu, and Bin Wang

Subjects

Anomaly detection (AD), hyperspectral images (HSIs), low-rank, sparsity, total variation (TV), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Anomaly detection (AD) aiming to locate targets distinct from the surrounding background spectra remains a challenging task in hyperspectral applications. The methods based on low-rank decomposition utilize the inherent low-rank characteristic of hyperspectral images (HSIs), which has attracted great interest and achieved many advances in recent years. In order to fully consider the characteristics of HSIs, more appropriate constrains need to be added to the low-rank model. However, there are too many regularizations and mutual constraints between regularizers, which would result in a reduction in detection accuracy, while an increasing number of tradeoff parameters complicates parameter tuning. To address the above problems, we propose a novel method based on merging total variation into low-rank representation (MTVLRR) for hyperspectral AD in this article, using a regularizer to reflect the low-rankness and smoothness of the background component of HSIs simultaneously, which can significantly decrease the mutual influence of regularizers and the difficulty of parameter tuning. Experimental results on both simulated and real hyperspectral datasets demonstrate that the proposed MTVLRR has an excellent AD performance in terms of detection accuracy compared with other state-of-the-art methods.

Published

2024

8. Spectral Indices Survey for Oil Spill Detection in Coastal Areas

Author

Ambar Perez-Garcia, Adrian Rodriguez-Molina, Emma Cristina Hernandez, and Jose Fco Lopez

Subjects

Hyperspectral images (HSIs), oil spill, remote sensing (RS), spectral indices, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

When oil spills occur at sea, effective detection and monitoring are required to establish a successful response plan, and remote sensing emerges as an appropriate technology to support this process. Furthermore, Earth observation is progressively relying on low-cost multispectral sensors developed for monitoring particular features across various scenarios. However, despite these advancements, the ongoing challenge lies in reducing computational costs, resource requirements, and energy consumption. This work aims to select the spectral index that best detects coastal spills among those documented. The long-term goal is to develop a low-cost multispectral sensor with suitable bands. For this purpose, this study uses data from different sensors that acquired data of the Deepwater Horizon accident in the Gulf of Mexico. The confusion matrices, accuracy, and F1-score generated from the kNN pixel classification based on the indices values are measures of its performance. For this study, the recently introduced normalized difference oil index (NDOI) proves to be the best option for identifying coastal spills since it minimizes the false positives related to suspended sand and is quick to calculate. In addition, it has demonstrated that it helps distinguish different spill thicknesses and estimates the oil volume. Therefore, future research will focus on developing and validating a low-cost multispectral system that uses the NDOI bands to detect spills.

Published

2024

9. Tucker Decomposition-Based Network Compression for Anomaly Detection With Large-Scale Hyperspectral Images

Author

Yulei Wang, Hongzhou Wang, Enyu Zhao, Meiping Song, and Chunhui Zhao

Subjects

Anomaly detection, convolutional neural network (CNN), hyperspectral images (HSIs), transfer learning, tucker decomposition, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Deep learning methodologies have demonstrated considerable effectiveness in hyperspectral anomaly detection (HAD). However, the practicality of deep learning-based HAD in real-world applications is impeded by challenges arising from limited labeled data, large-scale hyperspectral images (HSIs), and constrained computational resources. In light of these challenges, this article introduces a convolutional neural network (CNN)-based HAD model through the incorporation of Tucker decomposition, named TD-CNND. Drawing inspiration from transfer learning, the proposed model initially constructs pixel sample pairs from known labeled HSIs in the source domain, feeding them into the designed CNN to train the network learning spectral feature differences to obtain a CNN containing knowledge from the source domain. Subsequently, to prevent the need for network retraining caused by structural changes and to reduce model parameters for improving detecting timeliness, a general network compression scheme based on Tucker decomposition is applied to the CNN, where the convolutional layers of the above CNN undergo Tucker tensor decomposition to compress the network and alleviate parameter redundancy. Finally, spectral features realignment is used to recover the detection accuracy loss caused by Tucker tensor decomposition. In addition, a dual-windows structure is implemented during the detection phase, incorporating spatial information to the aforementioned spectral-level learning model, facilitating spectral-spatial collaborative HAD. Experimental evaluations using three real hyperspectral datasets and artificially expanded datasets demonstrate that, in comparison with state-of-the-art methods, the proposed TD-CNND method exhibits effectiveness and superiority in terms of both time cost and detection accuracy, where the notable advantages in terms of time cost become more pronounced with an increasing number of pixels.

Published

2024

10. Decentralized Federated GAN for Hyperspectral Change Detection in Edge Computing

Author

Weiying Xie, Xiaohong Xu, and Yunsong Li

Subjects

Blockchain, change detection (CD), federated learning (FL), generative adversarial network (GAN), hyperspectral images (HSIs), on-device learning, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Change detection on hyperspectral images (HSIs) is an essential task for Earth observation. Due to the vast amounts of remote sensing (RS) Big Data resulting from the ongoing advancements in RS hardware, employing centralized learning through cloud computing emerges as a logical and convenient solution. Nevertheless, this approach overlooks the influence of the isolation and heterogeneity of RS data on the reliability of change detection outcomes. In contrast, federated learning (FL) enables collaborative change detection on nonindependent identical distributed RS data without the need to transfer the original data. Simultaneously, it is important to acknowledge that the dependency of FL on the central node may pose potential data security risks. To address this issue, this article proposes a decentralized FL generative adversarial network (GAN) network. This ensures that raw data remains stationary during participation in unsupervised learning. In addition, the network employs edge devices to implement FL, allowing adaptation to diverse devices in practical scenarios. Lastly, blockchain is integrated into a decentralized architecture for the dynamic selection of leader nodes, effectively enhancing the robustness and security of the framework. Decentralized federated generative adversarial network (DFGAN) is a novel approach for cooperative privacy preservation introduced into hyperspectral change detection systems. The method outperforms most of existing methods on three datasets, achieving more than 90% detection accuracy on all of them. In addition, by simulating in a real on-orbit environment using a satellite constellation simulator on a Jeston TX2, FedGAN demonstrates superior accuracy in HSI change compared to existing algorithms while significantly reducing training time by 17.3%.

Published

2024

11. Dual Smooth Graph Convolutional Clustering for Large-Scale Hyperspectral Images

Author

Jiaxin Chen, Shujun Liu, and Huajun Wang

Subjects

Dual clustering network, feature extraction, feature fusion, graph convolutional network (GCN), hyperspectral images (HSIs), smooth graph filter, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Large-scale hyperspectral image (HSI) clustering remains a fundamental and challenging task due to tremendous spatial scales, abundant spectral band information, and lack of prior information. Most existing clustering methods either ignore the spectral band correlation leading to low clustering performance nor unprocessable due to the large spatial scale. To solve these difficulties, this article presents a dual smooth graph convolutional clustering (DSGCC) framework for large-scale HSI clustering. Specifically, the superpixel is introduced to decrease the spatial scale of HSI and reduce graph node number for subsequent network training. Furthermore, a smooth graph filter is presented, which extracts the smooth features and filters the high-frequency interference in graph learning. In addition, we propose a layerwise graph reconstruction mechanism, which constrains all hidden layers output by graph reconstruction loss. Finally, we introduce a self-training method that utilizes soft labels to supervise during clustering and learns the robust embedding for node clustering. DSGCC is an end-to-end network that is optimized by joint loss, which is easily trained from scratch. We assess DSGCC on five commonly used large-scale HSI datasets, and experiments denote that DSGCC achieves the optimum clustering performance, which is superior to existing HSI clustering approaches. On Salinas, Indian Pines, Pavia University, WHU-Hi-LongKou, and WHU-Hi-HongHu datasets, the clustering overall accuracy of DSGCC are 85.43%, 65.45%, 70.48%, 87.30%, and 77.34%, respectively.

Published

2024

12. Cloud-Based Analysis of Large-Scale Hyperspectral Imagery for Oil Spill Detection

Author

Juan M. Haut, Sergio Moreno-Alvarez, Rafael Pastor-Vargas, Ambar Perez-Garcia, and Mercedes E. Paoletti

Subjects

Cloud computing (CC), disaster monitoring, hyperspectral images (HSIs), remote sensing (RS), spectral indices, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Spectral indices are of fundamental importance in providing insights into the distinctive characteristics of oil spills, making them indispensable tools for effective action planning. The normalized difference oil index (NDOI) is a reliable metric and suitable for the detection of coastal oil spills, effectively leveraging the visible and near-infrared (VNIR) spectral bands offered by commercial sensors. The present study explores the calculation of NDOI with a primary focus on leveraging remotely sensed imagery with rich spectral data. This undertaking necessitates a robust infrastructure to handle and process large datasets, thereby demanding significant memory resources and ensuring scalability. To overcome these challenges, a novel cloud-based approach is proposed in this study to conduct the distributed implementation of the NDOI calculation. This approach offers an accessible and intuitive solution, empowering developers to harness the benefits of cloud platforms. The evaluation of the proposal is conducted by assessing its performance using the scene acquired by the airborne visible infrared imaging spectrometer (AVIRIS) sensor during the 2010 oil rig disaster in the Gulf of Mexico. The catastrophic nature of the event and the subsequent challenges underscore the importance of remote sensing (RS) in facilitating decision-making processes. In this context, cloud-based approaches have emerged as a prominent technological advancement in the RS field. The experimental results demonstrate noteworthy performance by the proposed cloud-based approach and pave the path for future research for fast decision-making applications in scalable environments.

Published

2024

13. SuperPCA and 2-D compact variational mode decomposition for feature extraction from hyperspectral images.

Author

Zhuo, Renxiong, Guo, Yunfei, Guo, Baofeng, Liu, Baoyang, and Dai, Fan

Subjects

*PRINCIPAL components analysis, *DATA mining, *SUPERPOSITION (Optics), *DIMENSION reduction (Statistics)

Abstract

The 2-D compact variational mode decomposition (2-D-C-VMD) has potential research significance in data mining of hyperspectral images (HSIs). The paper proposes a method of concatenation of features. First, the 2-D-C-VMD technique is used to decompose the HSIs to obtain smooth and clear boundary sub-band images when the 2-D-C-VMD takes the most preferred a priori parameter K ×. Second, the optimal low-frequency component features of the image and the optimal high-frequency component constructed features are concatenated first and last, and the structure of the concatenation is constructed into a new fused data. Finally, in order to avoid the redundancy of the fused data band information from affecting the classification result, combine a recently developed simple and practical superpixelwise principal component analysis (SuperPCA) dimensionality reduction method to effectively reduce the dimensionality of the fused data. By comparing the analysis with relying only on the optimal low-frequency image feature information and with the direct linear superposition fusion that has been employed, it is verified that the concatenation of features approach proposed in this paper can obtain better recognition results. [ABSTRACT FROM AUTHOR]

Published

2024

14. Cloud-Based Analysis of Large-Scale Hyperspectral Imagery for Oil Spill Detection.

Author

Haut, Juan M., Moreno-Alvarez, Sergio, Pastor-Vargas, Rafael, Perez-Garcia, Ambar, and Paoletti, Mercedes E.

Abstract

Spectral indices are of fundamental importance in providing insights into the distinctive characteristics of oil spills, making them indispensable tools for effective action planning. The normalized difference oil index (NDOI) is a reliable metric and suitable for the detection of coastal oil spills, effectively leveraging the visible and near-infrared (VNIR) spectral bands offered by commercial sensors. The present study explores the calculation of NDOI with a primary focus on leveraging remotely sensed imagery with rich spectral data. This undertaking necessitates a robust infrastructure to handle and process large datasets, thereby demanding significant memory resources and ensuring scalability. To overcome these challenges, a novel cloud-based approach is proposed in this study to conduct the distributed implementation of the NDOI calculation. This approach offers an accessible and intuitive solution, empowering developers to harness the benefits of cloud platforms. The evaluation of the proposal is conducted by assessing its performance using the scene acquired by the airborne visible infrared imaging spectrometer (AVIRIS) sensor during the 2010 oil rig disaster in the Gulf of Mexico. The catastrophic nature of the event and the subsequent challenges underscore the importance of remote sensing (RS) in facilitating decision-making processes. In this context, cloud-based approaches have emerged as a prominent technological advancement in the RS field. The experimental results demonstrate noteworthy performance by the proposed cloud-based approach and pave the path for future research for fast decision-making applications in scalable environments. [ABSTRACT FROM AUTHOR]

Published

2024

15. Hyperspectral images classification based on multiple kernel learning using SWT and KMNF with few training samples.

Author

Hassanzadeh, Shirin, Danyali, Habibollah, and Helfroush, Mohammad Sadegh

Subjects

*IMAGE recognition (Computer vision), *WAVELET transforms

Abstract

In this paper, a new techniquebased on Multiple kernel learning (MKL) with just a few training samples is proposed for HSI classification utilising stationary wavelet transform (SWT) and kernel minimal noise fraction (KMNF). 2D-SWT is applied to each spectral band to discriminate spatial information, and feature sets are created by concatenating wavelet bands. The base kernels associated with each feature set are constructed, and the optimum kernel for maximum separability is learned. The experimental results indicate that the suggested approach provides high accuracy with a low number of training samples and outperforms state-of-the-art MKL-based classifiers with no increase in computing complexity. [ABSTRACT FROM AUTHOR]

Published

2023

16. Progressive pseudo-label framework for unsupervised hyperspectral change detection

Author

Qiuxia Li, Tingkui Mu, Abudusalamu Tuniyazi, Qiujie Yang, and Haishan Dai

Subjects

Change detection (CD), Hyperspectral images (HSIs), Uncertainty estimation, Pseudo-label, Physical geography, GB3-5030, Environmental sciences, GE1-350

Abstract

For hyperspectral image change detection (HSI-CD) task, unsupervised learning methods based on pseudo-labels obtained from pre-classification method are promising due to its simplicity and generality. However, the inevitable noise and the lack of diversity in the pseudo-labels would degrade the performance of the network model, resulting in insufficient mining of fine change information in HSIs. To address this issue, we propose a progressive pseudo-label (PPL) framework for HSI-CD. Differing from the state-of-the-art methods of training designed networks with fixed pseudo-labels, we focus our attention on improving the quality of pseudo-labels progressively. In the PPL framework, a multi-scale pre-classification module is constructed for generating initial pseudo-labels. Subsequently, an uncertainty-aware selection strategy is designed to update the pseudo-labels. Specifically, the new pseudo-labels are selected based on the uncertainty estimated by the Bayesian network trained with pseudo-labels. The new pseudo-labels have richer diversity with quality assurance and thus called progressive pseudo-labels. Meanwhile, the Bayesian network trained by progressive pseudo-labels has increasingly better detection capability. As a result, the PPL framework can detect strong and subtle changes while suppressing false changes. Furthermore, the PPL framework additionally provides the uncertainty to evaluate the reliability of the prediction. We have implemented intensive experiments on three publicly available datasets demonstrate the outperformance and generalization of the PPL framework. The overall accuracy (OA) and Kappa metrics on the commonly used Hermiston dataset reached 0.9558 and 0.8728, respectively.

Published

2024

17. Advanced Hyperspectral Image Analysis: Superpixelwise Multiscale Adaptive T-HOSVD for 3D Feature Extraction

Author

Qiansen Dai, Chencong Ma, and Qizhong Zhang

Subjects

hyperspectral images (HSIs), image classification, tensor, low-rank representations, 3D feature extraction, multiscale, Chemical technology, TP1-1185

Abstract

Hyperspectral images (HSIs) possess an inherent three-order structure, prompting increased interest in extracting 3D features. Tensor analysis and low-rank representations, notably truncated higher-order SVD (T-HOSVD), have gained prominence for this purpose. However, determining the optimal order and addressing sensitivity to changes in data distribution remain challenging. To tackle these issues, this paper introduces an unsupervised Superpixelwise Multiscale Adaptive T-HOSVD (SmaT-HOSVD) method. Leveraging superpixel segmentation, the algorithm identifies homogeneous regions, facilitating the extraction of local features to enhance spatial contextual information within the image. Subsequently, T-HOSVD is adaptively applied to the obtained superpixel blocks for feature extraction and fusion across different scales. SmaT-HOSVD harnesses superpixel blocks and low-rank representations to extract 3D features, effectively capturing both spectral and spatial information of HSIs. By integrating optimal-rank estimation and multiscale fusion strategies, it acquires more comprehensive low-rank information and mitigates sensitivity to data variations. Notably, when trained on subsets comprising 2%, 1%, and 1% of the Indian Pines, University of Pavia, and Salinas datasets, respectively, SmaT-HOSVD achieves impressive overall accuracies of 93.31%, 97.21%, and 99.25%, while maintaining excellent efficiency. Future research will explore SmaT-HOSVD’s applicability in deep-sea HSI classification and pursue additional avenues for advancing the field.

Published

2024

18. Background Reconstruction via 3D-Transformer Network for Hyperspectral Anomaly Detection.

Author

Wu, Ziyu and Wang, Bin

Subjects

*ANOMALY detection (Computer security), *INTRUSION detection systems (Computer security), *PIXELS, *FALSE alarms, *DETECTORS

Abstract

Recently, autoencoder (AE)-based anomaly detection approaches for hyperspectral images (HSIs) have been extensively proposed; however, the reconstruction accuracy is susceptible to the anomalies and noises. Moreover, these AE-based anomaly detectors simply compress each pixel into a hidden-layer with a lower dimension and then reconstruct it, which does not consider the spatial properties among pixels. To solve the above issues, this paper proposes a background reconstruction framework via a 3D-transformer (3DTR) network for anomaly detection in HSIs. The experimental results on both synthetic and real hyperspectral datasets demonstrate that the proposed 3DTR network is able to effectively detect most of the anomalies by comprehensively considering the spatial correlations among pixels and the spectral similarity among spectral bands of HSIs. In addition, the proposed method exhibits fewer false alarms than both traditional and state-of-the-art (including model-based and AE-based) anomaly detectors owing to the adopted pre-detection procedure and the proposed novel patch-generation method in this paper. Moreover, two ablation experiments adequately verified the effectiveness of each component in the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

19. 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

20. Enhanced Tensor Low-Rank Representation Learning for Hyperspectral Anomaly Detection.

Author

Xiao, Qingjiang, Zhao, Liaoying, Chen, Shuhan, and Li, Xiaorun

Abstract

Nowadays, some tensor-based hyperspectral anomaly detection (HAD) approaches are still insufficient in utilizing the spatial–spectral structure information of hyperspectral images (HSIs), resulting in the inability to isolate the background and abnormal targets well. In this letter, an enhanced tensor low-rank representation (ETLR) learning model is proposed for HAD. Specifically, the original 3-D HSI data is first decomposed into a structural background component, an anomaly component, and a noise component. Among them, with the help of multisubspace learning technology, the structural background component is reformulated by the t-product of the background dictionary tensor and the corresponding coefficient tensor. Then, the tensor nuclear norm (TNN) is adopted to preserve the global low-rank property of the background component in both spatial and spectral dimensions. For the abnormal component, an $\ell _{2,1,1}$ -norm is designed to enhance the group sparsity of abnormal pixels. For the noise component, a tensor $F$ -norm constraint is imposed to suppress the confusion of noise and anomalies. Meanwhile, a robust dictionary tensor that can adequately characterize the background is constructed by using tensor robust principal component analysis (TRPCA). Furthermore, to reduce the interference of redundant information on detection accuracy, the optimal clustering framework (OCF) method is utilized for band selection. Finally, extensive experiments on one simulated and three real HSI datasets confirm that our algorithm is superior to current HAD algorithms. [ABSTRACT FROM AUTHOR]

Published

2023

21. Semisupervised Hyperspectral Image Classification Network Based on Pseudo-Label and Spatial–Spectral Convolution.

Author

Zhou, Kai, Wu, Yaruo, Xiang, Jianhong, Liu, Yang, and Wang, Minhui

Abstract

The accuracy of hyperspectral image (HSI) classification relies on lots of labeled training samples. However, the existing HSI data can be used for training with extremely limited labeled samples. In this letter, we propose a semisupervised HSI classification network based on pseudo-label and spatial-spectral convolution (PS3DN), which can improve classification accuracy with limited labeled samples. First, we design an asymmetric dense residual network (ARDN), which uses asymmetric convolution kernels instead of square kernels to reduce the number of parameters. Then we use the Center-Focus loss function to update the network parameters, aiming to improve the robustness of the network. Further, we generate high-confidence pseudo-labels by this network, which reduces the need for labeled samples for the classification network. Finally, we propose a joint spatial-spectral convolutional (SSCNN) classification network, the fusion of spatial-spectral separation convolution and self-learning attention mechanism, to achieve more accurate classification. We conducted experiments on four public datasets, and the experimental results show that the classification accuracy of Pavia University (UP), Salinas (SA), Kennedy Space Center (KSC), and Indian Pines (IP) datasets is 92.45%, 96.91%, 98.38%, and 90.43%, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

22. CS2DT: Cross Spatial–Spectral Dense Transformer for Hyperspectral Image Classification.

Author

Xu, Hao, Zeng, Zhigang, Yao, Wei, and Lu, Jiayue

Abstract

Compared with general optical images, hyperspectral images (HSIs) contain richer spectral information. On one hand, this provides a sufficient basis for ground object recognition. On the other hand, it results in the intermingling of spatial and spectral information. In order to make better use of the rich spatial and spectral information in HSIs, we resort to vision transformer (ViT). To be specific, we propose the cross spatial–spectral dense transformer (CS2DT) for spatial–spectral feature extracting and feature fusing. For feature extraction, CS2DT employs the adaptive dense encoder (ADE) module, which enables the extraction of multiscale semantic information. During the features fusion stage, we use the cross spatial–spectral attention (CS2A) module based on the cross-attention (CA) operation to better integrate spatial and spectral features. We evaluate the classification performance of the proposed CS2DT on three well-known datasets by conducting extensive experiments. Experimental results demonstrate that CS2DT can achieve higher accuracy and higher stability when compared with the state-of-the-art (SOTA) methods. The source code will be made available at https://github.com/shouhengx/CS2DT. [ABSTRACT FROM AUTHOR]

Published

2023

23. 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

24. 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

25. Semantic Segmentation Network for Classification of Hyperspectral Images With Small Size Samples.

Author

Ma, Li, Li, Shuyue, Zhou, Zhiyong, Yao, Yafeng, and Du, Qian

Abstract

A sparse label-oriented semantic segmentation network (SL-SSNet) is proposed for the classification of hyperspectral images (HSIs) in this letter. Since semantic segmentation network performs pixel-level classification and can extract long-range contextual information, we apply it to the task of HSI classification. To mitigate the small size sample problem, we not only design a lightweight fully convolutional network, but also explore the usefulness of unlabeled data by introducing two constraints. First, an adversarial learning-based multiclassifier consistency strategy is employed to improve the classification of unlabeled data. It constrains two different classifiers to have consistent prediction results on unlabeled data. As a result, the extracted features of unlabeled data can be more discriminative and the predictions are more reliable. Second, a manifold regularizer is applied to constrain the classification results of unlabeled data to be smooth with respect to the data manifold, which can further exploit the unlabeled data and alleviate the small size sample problem. The experimental results using multiple hyperspectral data demonstrate the efficiency of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

26. A Coarse-to-Fine Semisupervised Learning Method Based on Superpixel Graph and Breaking-Tie Sampling for Hyperspectral Image Classification.

Author

Zhao, Chunhui, Chen, Maoyang, Feng, Shou, Qin, Boao, and Zhang, Lifu

Abstract

At present, hyperspectral image classification (HSIC) technology based on deep learning has been widely explored. However, the time and labor costs of obtaining enough labeled samples are expensive. To obtain higher classification performance with a few number of labeled samples, a coarse-to-fine semisupervised classification learning (CFSSL) method is proposed in this letter. First of all, the CFSSL performs coarse-grained classification with a few number of labeled samples, and the breaking-ties (BTs) criterion is introduced to sample the coarse-grained classification results to ensure that the samples with high confidence are selected to generate pseudo-labels. Then, the pseudo-labels and their corresponding unlabeled samples are sent to the feature extraction network for fine-grained classification, to obtain more advanced classification results. Finally, in the fine-grained classification stage, a multiscale convolution kernel attention aggregation network ($A^{2}$ -MCKN) is designed to simultaneously extract the spatial-spectral features of the image and ensure clear texture boundaries of ground objects. The experimental results on two public datasets show that the CFSSL can obtain better accuracy than other methods with a few number of labeled samples. [ABSTRACT FROM AUTHOR]

Published

2023

27. Novel Spectral Loss Function for Unsupervised Hyperspectral Image Segmentation.

Author

Perez-Garcia, Ambar, Paoletti, Mercedes E., Haut, Juan M., and Lopez, Jose F.

Abstract

Neural networks (NNs) have gained importance in hyperspectral image (HSI) segmentation for earth observation (EO) due to their unparalleled data-driven feature extraction capability. However, in many real-life situations, ground truth is not available, and the performance of unsupervised NNs is still susceptible to enhancement. To overcome this challenge, this letter presents a new loss function to improve the performance of unsupervised HSI segmentation models. The spectral loss function, $Sl$ , which can be included in different models, is based on the purity of the unmixing endmembers and the spectral similarity of the clusters provided by the NN to determine the classes. It is incorporated into a 3-D convolutional autoencoder (AE) to validate its performance on four standard HSI benchmarks. Furthermore, its performance has been qualitatively examined in a real case study, an oil spill without ground truth. The results show that $Sl$ is a breakthrough in unsupervised HS segmentation, obtaining the best overall performance and highlighting the importance of spectral signatures. Additionally, the dimensional reduction is also vital in compacting the spectral information, which facilitates its segmentation. The source code is available at https://github.com/mhaut/HSI-3DSpLoss. [ABSTRACT FROM AUTHOR]

Published

2023

28. An Attention-Based Multiscale Spectral–Spatial Network for Hyperspectral Target Detection.

Author

Feng, Shou, Feng, Rui, Liu, Jianfei, Zhao, Chunhui, Xiong, Fengchao, and Zhang, Lifu

Abstract

Deep-learning-based methods have made great progress in hyperspectral target detection (HTD). Unfortunately, the insufficient utilization of spatial information in most methods leaves deep-learning-based methods to confront ineffectiveness. To ameliorate this issue, an attention-based multiscale spectral–spatial detector (AMSSD) for HTD is proposed. First, the AMSSD leverages the Siamese structure to establish a similarity discrimination network, which can enlarge intraclass similarity and interclass dissimilarity to facilitate better discrimination between the target and the background. Second, 1-D convolutional neural network (CNN) and vision Transformer (ViT) are used combinedly to extract spectral–spatial features more feasibly and adaptively. The joint use of spectral–spatial information can obtain more comprehensive features, which promotes subsequent similarity measurement. Finally, a multiscale spectral–spatial difference feature fusion module is devised to integrate spectral–spatial difference features of different scales to obtain more distinguishable representation and boost detection competence. Experiments conducted on two HSI datasets indicate that the AMSSD outperforms seven compared methods. [ABSTRACT FROM AUTHOR]

Published

2023

29. All of Low-Rank and Sparse: A Recast Total Variation Approach to Hyperspectral Denoising

Author

Haijin Zeng, Shaoguang Huang, Yongyong Chen, Hiep Luong, and Wilfried Philips

Subjects

Hyperspectral images (HSIs), restoration, spatial–spectral, total variation (TV), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral image (HSI) processing tasks frequently rely on spatial–spectral total variation (SSTV) to quantify the local smoothness of image structures. However, conventional SSTV only considers a sparse structure of gradient maps computed along the spatial and spectral dimensions while neglecting other correlations. To address this limitation, we introduce low-rank guided SSTV (LRSTV), which characterizes the sparsity and low-rank priors of the gradient map simultaneously. First, we verify through numerical tests and theoretical analyses that the gradient tensors are not only sparse but also low-rank. Subsequently, to model the low rankness of the gradient map, we use the tensor average rank to represent the low Tucker rank of gradient tensors. The convex envelope of the tensor average rank is then employed to penalize the rank on the gradient map after the Fourier transform along the spectral dimension. By naturally encoding the sparsity and low-rank priors of the gradient map, LRSTV results in a more accurate representation of the original image. Finally, we demonstrate the effectiveness of LRSTV by integrating it into the HSI processing model, replacing conventional SSTV, and testing it on two public datasets with nine cases of mixed noise and two datasets with realistic noise. The results show that LRSTV outperforms conventional SSTV in terms of accuracy and robustness.

Published

2023

30. Circle-Net: An Unsupervised Lightweight-Attention Cyclic Network for Hyperspectral and Multispectral Image Fusion

Author

Shuaiqi Liu, Siyu Miao, Siyuan Liu, Bing Li, Weiming Hu, and Yu-Dong Zhang

Subjects

Attention mechanism, deep learning (DL), hyperspectral images (HSIs), image fusion, multispectral images (MSIs), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral image (HSI) and multispectral image (MSI) fusion has the potential to significantly improve the quality and usefulness of data, leading to better decision-making and a more complete understanding of the observed scene. For HSI and MSI fusion, capturing matched pairs of HSI and MSI images is challenging. This hampers the pretraining of neural-network-based HSI–MSI fusion methods and yields unsatisfactory fusion results. A lightweight-attention (LA) cyclic network (Circle-Net) without pretraining using labeled data is constructed and applied to HSI–MSI fusion to alleviate this issue. Circle-Net consists of a coordinate feature fusion (CFF) network and a dual-attention decoder (DAD) network. Multiscale features collected from the DAD network are fused by the CFF network to derive a high-resolution HSI. Specifically, in the DAD network, skip connections in the encoder–decoder network are replaced by LAs, while polarized attention is used to guarantee efficient transfer of features between the encoder and decoder. In comparison with other methods, the experimental performance shows the superiority of the Circle-Net in both visual and quantitative performance.

Published

2023

31. Dual Collaborative Constraints Regularized Low-Rank and Sparse Representation via Robust Dictionaries Construction for Hyperspectral Anomaly Detection

Author

Sheng Lin, Min Zhang, Xi Cheng, Kexue Zhou, Shaobo Zhao, and Hai Wang

Subjects

Anomaly detection, dual collaborative constraints, hyperspectral images (HSIs), low-rank and sparse representation (LRSR), robust dictionaries construction, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

The low rank and sparse representation (LRSR) technique has attracted increasing attention for hyperspectral anomaly detection (HAD). Although a large quantity of research based on LRSR for HAD is proposed, the detection performance is still limited, due to the unsatisfactory dictionary construction and insufficient consideration of global and local characteristics. To tackle the above-mentioned concern, a novel HAD method, termed dual collaborative constraints regularized low-rank and sparse representation via robust dictionaries construction, is proposed in this article. Concretely, a robust dictionary construction strategy, which thoroughly excavates the potential of the density estimation model and local outlier factor, is proposed to yield pure and representative dictionary atoms. To fully exploit the global and local characteristics of hyperspectral images, dual collaborative constraints corresponding to the background and anomaly components are imposed on the LRSR model. Notably, two weighted matrices are further exerted on the representation coefficients to improve the effect of collaborative constraints, considering the fact that the surrounding pixels similar to the testing pixel should be given a large weight, otherwise the weight is expected to be small. In this way, the background and anomaly components can be well modeled. Additionally, a nonlinear transformation operation, which combines the output of the density estimation model and local outlier factor with the detection result derived from the LRSR model, is developed to suppress the background. The experiments conducted on one simulated dataset and three real datasets demonstrate the superiority of the proposed method compared with the four typical methods and four state-of-the-art methods.

Published

2023

32. Hyperspectral Anomaly Detection via Sparse Representation and Collaborative Representation

Author

Sheng Lin, Min Zhang, Xi Cheng, Kexue Zhou, Shaobo Zhao, and Hai Wang

Subjects

Anomaly detection, collaborative representation (CR), guided filter, hyperspectral images (HSIs), sparse representation (SR), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Sparse representation (SR)-based approaches and collaborative representation (CR)-based methods are proved to be effective to detect the anomalies in a hyperspectral image (HSI). Nevertheless, the existing methods for achieving hyperspectral anomaly detection (HAD) generally only consider one of them, failing to comprehensively exploit them to further promote the detection performance. To address the issue, a novel HAD method, which integrates both SR and CR, is proposed in this article. To be specific, an SR model, whose overcomplete dictionary is generated by means of the density-based clustering algorithm and superpixel segmentation method, is first constructed for each pixel in an HSI. Then, for each pixel in an HSI, the used atoms in SR model are sifted to form the background dictionary corresponding to the CR model. To fully exploit both SR and CR information, we further combine the residual features obtained from both SR and CR model by the nonlinear transformation function to generate the response map. Finally, to preserve contour information of the objects, a postprocessing operation with guided filter is imposed into the response map to acquire the detection result. Experiments conducted on simulated and real datasets demonstrate that the proposed SRCR outperforms the state-of-the-art methods.

Published

2023

33. Multi-Scale Spectral-Spatial Attention Network for Hyperspectral Image Classification Combining 2D Octave and 3D Convolutional Neural Networks.

Author

Liang, Lianhui, Zhang, Shaoquan, Li, Jun, Plaza, Antonio, and Cui, Zhi

Subjects

*CONVOLUTIONAL neural networks, *IMAGE recognition (Computer vision), *DEEP learning, *INFORMATION networks

Abstract

Traditional convolutional neural networks (CNNs) can be applied to obtain the spectral-spatial feature information from hyperspectral images (HSIs). However, they often introduce significant redundant spatial feature information. The octave convolution network is frequently utilized instead of traditional CNN to decrease spatial redundant information of the network and extend its receptive field. However, the 3D octave convolution-based approaches may introduce extensive parameters and complicate the network. To solve these issues, we propose a new HSI classification approach with a multi-scale spectral-spatial network-based framework that combines 2D octave and 3D CNNs. Our method, called MOCNN, first utilizes 2D octave convolution and 3D DenseNet branch networks with various convolutional kernel sizes to obtain complex spatial contextual feature information and spectral characteristics, separately. Moreover, the channel and the spectral attention mechanisms are, respectively, applied to these two branch networks to emphasize significant feature regions and certain important spectral bands that comprise discriminative information for the categorization. Furthermore, a sample balancing strategy is applied to address the sample imbalance problem. Expansive experiments are undertaken on four HSI datasets, demonstrating that our MOCNN approach outperforms several other methods for HSI classification, especially in scenarios dominated by limited and imbalanced sample data. [ABSTRACT FROM AUTHOR]

Published

2023

34. Spectral Mixing Theory-Based Double-Branch Network for Spectral Super-Resolution.

Author

Sha, Lingyu, Zhang, Wenjuan, Zhang, Bing, Liu, Zhiqiang, and Li, Zhen

Subjects

*IMAGING systems, *MULTISPECTRAL imaging, *CONVOLUTIONAL neural networks, *FOUR-wave mixing, *SYNTHETIC aperture radar

Abstract

Due to the limitations of imaging systems, the swath width of available hyperspectral images (HSIs) is relatively narrow, making it difficult to meet the demands of various applications. Therefore, an appealing idea is to expand the width of HSIs by using widely covered multispectral images (MSIs), called spectral super-resolution (SSR) of MSIs. According to the radiation transmission process of the imaging system, the spectral mixing characteristics of ground objects can be described by the linear spectral mixing model (LSMM). Inspired by the linear mixed part and nonlinear residual part of the LSMM, we propose a double-branch SSR network. To generate wide HSIs, a spectral mixing branch is designed to extract abundances from wide MSIs and adaptively learn hyperspectral endmembers from narrow HSIs. Furthermore, considering the nonlinear factors in the imaging system and atmospheric transmission, a nonlinear residual branch is built to complement the spectral and spatial details. Finally, the SSR result can be obtained with the fusion of linear and nonlinear features. To make the network structure achieve corresponding physical significance, we constrain the network through joint loss functions at different stages. In addition to two simulated datasets with limited coverage, our model is also evaluated on a real MSI–HSI dataset in a larger area. Extensive experiments show the superiority of the proposed model compared with state-of-the-art baselines. Moreover, we visualized the internal results of our network and conducted ablation experiments on a single branch to further demonstrate its effectiveness. In the end, the influence of network hyperparameters, including endmembers and loss function weight coefficient, is discussed and analyzed in detail. [ABSTRACT FROM AUTHOR]

Published

2023

35. Maize disease detection based on spectral recovery from RGB images.

Author

Jun Fu, Jindai Liu, Rongqiang Zhao, Zhi Chen, Yongliang Qiao, and Dan Li

Subjects

CONVOLUTIONAL neural networks, AGRICULTURAL robots, CORN, EARLY diagnosis

Abstract

Maize is susceptible to infect pest disease, and early disease detection is key to preventing the reduction of maize yields. The raw data used for plant disease detection are commonly RGB images and hyperspectral images (HSI). RGB images can be acquired rapidly and low-costly, but the detection accuracy is not satisfactory. On the contrary, using HSIs tends to obtain higher detection accuracy, but HSIs are difficult and high-cost to obtain in field. To overcome this contradiction, we have proposed the maize spectral recovery disease detection framework which includes two parts: the maize spectral recovery network based on the advanced hyperspectral recovery convolutional neural network (HSCNN+) and the maize disease detection network based on the convolutional neural network (CNN). Taking raw RGB data as input of the framework, the output reconstructed HSIs are used as input of disease detection network to achieve disease detection task. As a result, the detection accuracy obtained by using the low-cost raw RGB data almost as same as that obtained by using HSIs directly. The HSCNN+ is found to be fit to our spectral recovery model and the reconstruction fidelity was satisfactory. Experimental results demonstrate that the reconstructed HSIs efficiently improve detection accuracy compared with raw RGB image in tested scenarios, especially in complex environment scenario, for which the detection accuracy increases by 6.14%. The proposed framework has the advantages of fast, low cost and high detection precision. Moreover, the framework offers the possibility of real-time and precise field disease detection and can be applied in agricultural robots. [ABSTRACT FROM AUTHOR]

Published

2022

36. Background Reconstruction via 3D-Transformer Network for Hyperspectral Anomaly Detection

Author

Ziyu Wu and Bin Wang

Subjects

hyperspectral images (HSIs), anomaly detection, transformer (TR), background reconstruction, patch, coarse pre-detection, Science

Abstract

Recently, autoencoder (AE)-based anomaly detection approaches for hyperspectral images (HSIs) have been extensively proposed; however, the reconstruction accuracy is susceptible to the anomalies and noises. Moreover, these AE-based anomaly detectors simply compress each pixel into a hidden-layer with a lower dimension and then reconstruct it, which does not consider the spatial properties among pixels. To solve the above issues, this paper proposes a background reconstruction framework via a 3D-transformer (3DTR) network for anomaly detection in HSIs. The experimental results on both synthetic and real hyperspectral datasets demonstrate that the proposed 3DTR network is able to effectively detect most of the anomalies by comprehensively considering the spatial correlations among pixels and the spectral similarity among spectral bands of HSIs. In addition, the proposed method exhibits fewer false alarms than both traditional and state-of-the-art (including model-based and AE-based) anomaly detectors owing to the adopted pre-detection procedure and the proposed novel patch-generation method in this paper. Moreover, two ablation experiments adequately verified the effectiveness of each component in the proposed method.

Published

2023

37. Hyperspectral anomaly detection using ensemble and robust collaborative representation.

Author

Wang, Shaoxi, Hu, Xintao, Sun, Jialong, and Liu, Jinzhuo

Subjects

*ANOMALY detection (Computer security), *BATCH processing, *PARALLEL programming, *PIXELS, *SPECTRAL imaging

Abstract

In this paper, we propose a novel ensemble and robust anomaly detection method based on collaborative representation-based detector. The focused pixels used to estimate the background data are randomly sampled from the image. To soften the outliers' contributions among the selected pixels, we assign low weights to the outliers by adopting a robust norm regression. Consequently, the estimation result is less sensitive to the presence of outliers, as the experiment results attest. However, the algorithm performance is unstable due to the randomness of pixel sampling. To eliminate the instability and boost the detection performance, an ensemble learning method is employed. We repeat modeling background based on random pixel selection, and the detection result is an ensemble of all batches. We show that in most datasets, the proposed method outperforms the traditional algorithms. Moreover, batch processes for detection boosting secure future advances in performance utilization with parallel computing applied. [ABSTRACT FROM AUTHOR]

Published

2023

38. Mixed Noise Removal for Hyperspectral Image With ${l_{0}}$-${l_{1 - 2}}$SSTV Regularization

Author

Li Zhang, Yan Qian, Jingmin Han, Puhong Duan, and Pedram Ghamisi

Subjects

${l_{0}}$ gradient, hyperspectral images (HSIs), mixed noise removal, spatial–spectral total variation (SSTV), weighted difference, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral images (HSIs) are usually corrupted by various types of mixed noises, which degrades the qualities of acquired images and limits the subsequent applications. In this article, we propose a novel denoised method based on a hybrid spatial–spectral total variation (SSTV) regularization, which we refer to as ${l_{0}}$-${l_{1 - 2}}$SSTV. Specifically, ${l_{0}}$-${l_{1 - 2}}$SSTV can be treated as an integrated regularization embedding spatial–spectral ${l_{0}}$ gradient model into ${l_{1 - 2}}$SSTV. ${l_{1 - 2}}$SSTV regularization exploits the sparse structures in both spatial and spectral domains. Hence, the correlations within HSIs are fully considered. Due to the good performance of ${l_{1 - 2}}$-norm in image restoration, ${l_{1 - 2}}$SSTV gives a tighter approximation for the gradient domains of HSIs. It can effectively avoid artifacts and oversmoothing caused by the limitation of the SSTV regularization based on ${l_{1}}$-norm (${l_{1}}$SSTV). Meanwhile, the ${l_{0}}$ gradient regularization controls the number of nonzero gradients to promote the local piecewise smoothness, making denoised images preserve clear edges. With the effective combination of ${l_{1 - 2}}$SSTV and ${l_{0}}$ gradient regularization, ${l_{0}}$-${l_{1 - 2}}$SSTV produces high-quality restoration results in the denoising process: better detail preservation and sharper edges. The augmented Lagrangian method and the difference of convex algorithm are exploited to optimize the proposed model. The results for simulated and real experiments demonstrate the effectiveness and superiority of the proposed method compared with state-of-the-art methods.

Published

2022

39. Adaptive Local Discriminant Analysis and Distribution Matching for Domain Adaptation in Hyperspectral Image Classification

Author

Yujie Ning, Jiangtao Peng, Lin Sun, Yi Huang, Weiwei Sun, and Qian Du

Subjects

Adaptive local discriminant analysis, distribution matching, domain adaptation (DA), hyperspectral images (HSIs), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Multimodally distributed data is very common in remote sensing images, such as hyperspectral images (HSIs). It is important to capture the local manifold structure while preserving the global discriminant information in the multimodal data. In this article, an adaptive local discriminant analysis and distribution matching (ALDADM) method is designed for the domain adaptation (DA) in HSI classification. ALDADM uses adaptive local discriminant analysis to extract features that are discriminative and robust to multimodally distributed data. Meanwhile, considering the spectral properties of HSI, the domain shift is reduced by distribution matching and subspace alignment. During this learning process, ALDADM only selects density peak samples to reduce the influence of interfering samples. Four DA tasks are designing using University of Pavia, Center of Pavia, Yancheng, and Botswana HSI datasets. Compared with existing DA methods, the experimental results demonstrate that our ALDADM offers a superior performance.

Published

2022

40. Hyperspectral and Multispectral Data Fusion via Joint Local-Nonlocal Modeling and Truncation Operator

Author

Jiawei Jiang, Yuchao Feng, Honghui Xu, Guojiang Shen, and Jianwei Zheng

Subjects

Hyperspectral images (HSIs), image fusion, manifold model, patch-based method, superresolution, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Fusion technology has been the core strategy to obtain a high-spatial-spectral resolution hyperspectral image (HSI). In recent years, few fusion models focused on exploiting the underlying manifold structure in the spatial dimension of the high-resolution HSI. We assume that image patches of high-resolution multispectral image (HR-MSI) and high-resolution hyperspectral image (HR-HSI) share similar manifold structures. Through this bridge, a local-nonlocal low-dimensional manifold defined from HR-MSI is built to favor the patch relationship in HR-HSI, which is further utilized to build a set of orthogonal bases. Subsequently, we introduce a truncation operation based on the adaptively constructed orthogonal bases, which can efficiently preserve the low-frequency information of the image and reduce the interference of noise. Finally, we combine the local-nonlocal manifold term and the truncation operation, coined as LNTM, into a variational super-resolution framework to regularize the latent HR-HSI, leading to a strongly convex function regarding the fusion problem. The cost function is solved by a carefully designed variant of alternating direction method of multipliers algorithm. Different experiments on three public benchmarks validate our algorithm outperforms the recent start-of-the-arts concerning both visual quality and numerical metrics.

Published

2022

41. 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

42. Self-Adaptive Low-Rank and Sparse Decomposition for Hyperspectral Anomaly Detection

Author

Qunming Wang, Jiang Zeng, Hao Wu, Jiawen Wang, and Kaipeng Sun

Subjects

Anomaly detection, hyperspectral images (HSIs), low-rank and sparse decomposition, noise suppression, self-adaptive, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral anomaly detection is a widely used technique for exploring target of interest in hyperspectral images (HSIs). In recent years, the low-rank and sparse-decomposition-based anomaly detection model has attracted extensive attention. However, these models suffer from two main problems. First, it is difficult for them to completely separate the low-rank background and the sparse anomaly. Moreover, the extracted sparse component is inevitably contaminated by noise. Second, the incorporation of various constraints increases the cost of selecting the optimal parameters. To solve the two key problems, we propose a self-adaptive low-rank and sparse decomposition (SLaSD) method for hyperspectral anomaly detection in this article. The proposed method decomposes the sparse (anomaly) part of the HSI through a novel self-adaptive alternating direction method (S-ADM). The noise of the sparse part is suppressed through a dual strategy of integrating guided filter and the difference between the S-ADM-derived sparse features of pixels. The performance of the proposed method is evaluated by comparing with ten state-of-the-art methods using six real HSIs. It is shown that the proposed SLaSD method can produce more accurate detection results than the ten benchmark methods.

Published

2022

43. Novel Data-Driven Spatial-Spectral Correlated Scheme for Dimensionality Reduction of Hyperspectral Images

Author

Yanming Zhang, Ping Yuan, Lijun Jiang, and Hong Tat Ewe

Subjects

Cube dynamic mode decomposition (CubeDMD), hyperspectral images (HSIs), reconstruction, three-order tensor, unsupervised dimensionality reduction, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Hyperspectral imaging technology has been popularly applied in remote sensing because it collects echoed signals from across the electromagnetic (EM) spectrum and thereby contributes fruitfully spatial-spectral information. However, the processing or storage of high-data-volume hyperspectral images (HSIs), also viewed as snapshots varying with the EM spectrum, burdens the hardware resources, especially for the high spectral resolution and spatial resolution cases. To address this challenge, a novel unsupervised dimensionality reduction method based on the dynamic mode decomposition (DMD) algorithm is proposed to analyze hyperspectral data. This method decomposes the spatial-spectral HSIs in terms of spatial dynamic modes and corresponding spectral patterns. Then, these spatial-spectral patterns are combined to reconstruct the raw HSIs via a low-rank model. Furthermore, we extend the proposed DMD method to hyperspectral data in the tensor form and title it CubeDMD to actualize the compression of HSIs in horizontal, vertical, and spectral dimensions. Our proposed data-driven scheme is benchmarked by the real hyperspectral data measured at the Salinas scenes and Pavia University. It is demonstrated that the HSIs can be reconstructed accurately and effectively by the proposed low-rank model. The mean peak signal-to-noise ratio between the reconstructed and original HSIs can reach 31.47 dB, and the corresponding mean spectral angle mapper is only 0.1037. Our work provides a useful tool for the analysis of HSIs with a low-rank representation.

Published

2022

44. Kernel Minimum Noise Fraction Transformation-Based Background Separation Model for Hyperspectral Anomaly Detection.

Author

Xue, Tianru, Jia, Jianxin, Xie, Hui, Zhang, Changxing, Deng, Xuan, and Wang, Yueming

Subjects

*ANOMALY detection (Computer security), *FRACTIONS, *NOISE, *SPATIAL resolution, *DATA mining, *DETECTORS

Abstract

A significant challenge in methods for anomaly detection (AD) in hyperspectral images (HSIs) is determining how to construct an efficient representation for anomalies and background information. Considering the high-order structures of HSIs and the estimation of anomalies and background information in AD, this article proposes a kernel minimum noise fraction transformation-based background separation model (KMNF-BSM) to separate the anomalies and background information. First, spectral-domain KMNF transformation is performed on the original hyperspectral data to fully mine the high-order correlation between spectral bands. Then, a BSM that combines the outlier removal, the iteration strategy, and the Reed–Xiaoli detector (RXD) is proposed to obtain accurate anomalous and background pixel sets based on the extracted features. Finally, the anomalous and background pixel sets are used as input for anomaly detectors to improve the background suppression and anomaly detection capabilities. Experiments on several HSIs with different spatial and spectral resolutions over different scenes are performed. The results demonstrate that the KMNF-BSM-based algorithms have better target detectability and background suppressibility than other state-of-the-art algorithms. [ABSTRACT FROM AUTHOR]

Published

2022

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

Author

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

Subjects

vision transformer, convolutional neural networks (CNNs), feature representations, hyperspectral images (HSIs), semantic segmentation, Science

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.

Published

2023

46. Crop type classification with hyperspectral images using deep learning : a transfer learning approach

Author

Patel, Usha, Pathan, Mohib, Kathiria, Preeti, and Patel, Vibha

Published

2023

47. 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

48. Sparse Unmixing Based on Adaptive Loss Minimization.

Author

Zhang, Xinxin, Yuan, Yuan, and Li, Xuelong

Subjects

*MATHEMATICAL optimization, *SPARSE matrices, *IMAGE reconstruction, *PRIOR learning

Abstract

Sparse unmixing (SU) algorithms use the existing spectral library as prior knowledge to analyze the endmembers and estimate abundance maps. The majority of SU algorithms use loss functions based on the $L_{2,1}$ -norm or $F$ -norm to minimize reconstruction error. They have different advantages and shortcomings. In short, $F$ -norm has a differentiable characteristic, and it is easy to minimize as a loss function. However, it is very sensitive to heavy noise and outliers. While the $L_{2,1}$ -norm emphasizes the reconstruction error on each band and is robust to noise with different intensities in different bands. But the $L_{2,1}$ -norm is nondifferentiable at zero-point. This article introduces an adaptive loss function based on the $\sigma $ -norm for SU, which combines the advantages of the $L_{2,1}$ -norm and $F$ -norm. The adaptive loss function is related to a nonnegative parameter $\sigma $. By adjusting the parameter $\sigma $ , the adaptive loss function can approach the $F$ -norm or $L_{2,1}$ -norm. To the best of our knowledge, it is the first time to apply an adaptive loss function to SU. Moreover, the adaptive loss function is globally differentiable, and we propose an optimization algorithm for the adaptive loss function and verify its convergence. Experiments on real-world and synthetic HSIs show that the adaptive loss function effectively enhances the performance of the SU algorithms. [ABSTRACT FROM AUTHOR]

Published

2022

49. 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

50. Multiobjective Optimization-Based Hyperspectral Band Selection for Target Detection.

Author

Song, Meiping, Liu, Shihui, Xu, Dayong, and Yu, Haoyang

Subjects

*SWARM intelligence, *PARTICLE swarm optimization, *SIGNAL-to-noise ratio

Abstract

Band selection can reduce information redundancy and improve application efficiency of hyperspectral images (HSIs), such as classification. Traditional band selection methods usually weight different objectives and combine them together in a single function, making it difficult to balance conflict between various criteria. Recently, multiobjective optimization band selection (MOBS) techniques have got a lot of attention, which evaluate bands from different aspects separately and search for a solution well-balancing all the objectives simultaneously. However, few algorithms are focused on target detection, and most of them use just two objectives, which are not sufficient enough to select optimal band subset for detection. To alleviate these problems, this article proposes an algorithm named target-oriented multiobjective optimization of band selection (TOMOBS). First, the multiobjective optimization (MO) framework with three objective functions is modeled, involving information, noise, and correlation of the bands, respectively. Second, to optimize the proposed model, the noninferior solution advantage matrix (NAM) is designed based on the swarm intelligence optimization method, which can provide accurate solutions and improve the descriptiveness of MO problems (MOPs). Third, a target-oriented evaluation mechanism is developed to guide selecting final result from the Pareto front (PF), especially designed for target detection. Experiments on real hyperspectral datasets show that this algorithm can provide a subset of bands with strong representational capability for target detection and achieve impressing results compared with the state-of-the-art methods. [ABSTRACT FROM AUTHOR]

Published

2022