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2021 Vol. 30, No. 2

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Graph-Based Dimensionality Reduction for Hyperspectral Imagery: A Review
Zhen Ye, Shihao Shi, Zhan Cao, Lin Bai, Cuiling Li, Tao Sun, Yongqiang Xi
2021, 30(2): 91-112. doi:10.15918/j.jbit1004-0579.2021.012
[Abstract](1062) [FullText HTML](551) [PDF 9474KB](221)
Abstract:
Hyperspectral image (HSI) contains a wealth of spectral information, which makes fine classification of ground objects possible. In the meanwhile, overly redundant information in HSI brings many challenges. Specifically, the lack of training samples and the high computational cost are the inevitable obstacles in the design of classifier. In order to solve these problems, dimensionality reduction is usually adopted. Recently, graph-based dimensionality reduction has become a hot topic. In this paper, the graph-based methods for HSI dimensionality reduction are summarized from the following aspects. 1) The traditional graph-based methods employ Euclidean distance to explore the local information of samples in spectral feature space. 2) The dimensionality-reduction methods based on sparse or collaborative representation regard the sparse or collaborative coefficients as graph weights to effectively reduce reconstruction errors and represent most important information of HSI in the dictionary. 3) Improved methods based on sparse or collaborative graph have made great progress by considering global low-rank information, local intra-class information and spatial information. In order to compare typical techniques, three real HSI datasets were used to carry out relevant experiments, and then the experimental results were analysed and discussed. Finally, the future development of this research field is prospected.
Multi-Scale PIIFD for Registration of Multi-Source Remote Sensing Images
Chenzhong Gao, Wei Li
2021, 30(2): 113-124. doi:10.15918/j.jbit1004-0579.2021.016
[Abstract](1537) [FullText HTML](778) [PDF 1079KB](107)
Abstract:
This paper aims at providing multi-source remote sensing images registered in geometric space for image fusion. Focusing on the characteristics and differences of multi-source remote sensing images, a feature-based registration algorithm is implemented. The key technologies include image scale-space for implementing multi-scale properties, Harris corner detection for keypoints extraction, and partial intensity invariant feature descriptor (PIIFD) for keypoints description. Eventually, a multi-scale Harris-PIIFD image registration algorithm framework is proposed. The experimental results of fifteen sets of representative real data show that the algorithm has excellent, stable performance in multi-source remote sensing image registration, and can achieve accurate spatial alignment, which has strong practical application value and certain generalization ability.
Geometric Calibration and Image Quality Assessment of High Resolution Dual-Camera Satellite
Zhou Fang, Xinrong Wang, Wei Ji, Meng Xu, Yinan Zhang, Yan Li, Longfei Li
2021, 30(2): 125-138. doi:10.15918/j.jbit1004-0579.2021.003
[Abstract](849) [FullText HTML](391) [PDF 1394KB](58)
Abstract:
The evaluation of geometric calibration accuracy of high resolution satellite images has been increasingly recognized in recent years. In order to evaluate geometric accuracy for dual-camera satellite images based on the ground control points (GCP), a rigorous geometric imaging model, which was based on the collinear equation of the probe directional angle and the optimized tri-axial attitude determination (TRIAD) algorithm, is presented. Two reliable test fields in Tianjin and Jinan (China) were utilized for geometric accuracy validation of Pakistan Remote Sensing Satellite-1. The experimental results demonstrate a certain deviation of the on-orbit calibration result from the initial design values of the calibration parameters. Therefore, on-orbit geometric calibration is necessary for optical satellite imagery. Within this research, the geometrical performances including positioning accuracy without/with GCP and band registration of the dual-camera satellite were analyzed in detail, and the results of geometric image quality are assessed and discussed. As a result, it is feasible and necessary to establish such a geometric calibration model to evaluate the geometric quality of dual-camera satellite.
Local Preserving Graphs Using Intra-Class Competitive Representation for Dimensionality Reduction of Hyperspectral Image
Zhen Ye, Shihao Shi, Tao Sun, Lin Bai
2021, 30(2): 139-158. doi:10.15918/j.jbit1004-0579.2021.013
[Abstract](667) [FullText HTML](351) [PDF 1701KB](32)
Abstract:
As a key technique in hyperspectral image pre-processing, dimensionality reduction has received a lot of attention. However, most of the graph-based dimensionality reduction methods only consider a single structure in the data and ignore the interfusion of multiple structures. In this paper, we propose two methods for combining intra-class competition for locally preserved graphs by constructing a new dictionary containing neighbourhood information. These two methods explore local information into the collaborative graph through competing constraints, thus effectively improving the overcrowded distribution of intra-class coefficients in the collaborative graph and enhancing the discriminative power of the algorithm. By classifying four benchmark hyperspectral data, the proposed methods are proved to be superior to several advanced algorithms, even under small-sample-size conditions.
OBH-RSI: Object-Based Hierarchical Classification Using Remote Sensing Indices for Coastal Wetland
Zhaoyang Lin, Jianbu Wang, Wei Li, Xiangyang Jiang, Wenbo Zhu, Yuanqing Ma, Andong Wang
2021, 30(2): 159-171. doi:10.15918/j.jbit1004-0579.2021.014
[Abstract](464) [FullText HTML](158) [PDF 1117KB](30)
Abstract:
With the deterioration of the environment, it is imperative to protect coastal wetlands. Using multi-source remote sensing data and object-based hierarchical classification to classify coastal wetlands is an effective method. The object-based hierarchical classification using remote sensing indices (OBH-RSI) for coastal wetland is proposed to achieve fine classification of coastal wetland. First, the original categories are divided into four groups according to the category characteristics. Second, the training and test maps of each group are extracted according to the remote sensing indices. Third, four groups are passed through the classifier in order. Finally, the results of the four groups are combined to get the final classification result map. The experimental results demonstrate that the overall accuracy, average accuracy and kappa coefficient of the proposed strategy are over 94% using the Yellow River Delta dataset.
Deep Multimodal Learning and Fusion Based Intelligent Fault Diagnosis Approach
Huifang Li, Jianghang Huang, Jingwei Huang, Senchun Chai, Leilei Zhao, Yuanqing Xia
2021, 30(2): 172-185. doi:10.15918/j.jbit1004-0579.2021.017
[Abstract](1492) [FullText HTML](596) [PDF 1406KB](86)
Abstract:
Industrial Internet of Things (IoT) connecting society and industrial systems represents a tremendous and promising paradigm shift. With IoT, multimodal and heterogeneous data from industrial devices can be easily collected, and further analyzed to discover device maintenance and health related potential knowledge behind. IoT data-based fault diagnosis for industrial devices is very helpful to the sustainability and applicability of an IoT ecosystem. But how to efficiently use and fuse this multimodal heterogeneous data to realize intelligent fault diagnosis is still a challenge. In this paper, a novel Deep Multimodal Learning and Fusion (DMLF) based fault diagnosis method is proposed for addressing heterogeneous data from IoT environments where industrial devices coexist. First, a DMLF model is designed by combining a Convolution Neural Network (CNN) and Stacked Denoising Autoencoder (SDAE) together to capture more comprehensive fault knowledge and extract features from different modal data. Second, these multimodal features are seamlessly integrated at a fusion layer and the resulting fused features are further used to train a classifier for recognizing potential faults. Third, a two-stage training algorithm is proposed by combining supervised pre-training and fine-tuning to simplify the training process for deep structure models. A series of experiments are conducted over multimodal heterogeneous data from a gear device to verify our proposed fault diagnosis method. The experimental results show that our method outperforms the benchmarking ones in fault diagnosis accuracy.
Design and Implementation of Partial Shared Digital Channelized Receiver
Lei Shi, Zhen Huang, Xuefeng Feng
2021, 30(2): 186-193. doi:10.15918/j.jbit1004-0579.2021.022
[Abstract](386) [FullText HTML](147) [PDF 1050KB](33)
Abstract:
A novel efficient partial sharing channelization structure with odd and even stacking is designed and implemented. There are two special designs in the proposed structure. Firstly, by the intensive channel overlap design, for non-cooperative wideband signals, the proposed structure can achieve good parameter estimation accuracy and high probability of complete interception. Secondly, based on the partial sharing design developed in this paper, the computation burden of the proposed structure can be greatly reduced compared with the traditional directly implemented structures. Experiments and numerical simulations are conducted to evaluate the proposed structure, which shows its improvements over traditional methods in terms of field programmable gate arrays (FPGA) resource consumption and parameter estimation accuracy.

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