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103 results on '"Xiong, Fengchao"'

1. SSUMamba: Spatial-Spectral Selective State Space Model for Hyperspectral Image Denoising

Author

Fu, Guanyiman, Xiong, Fengchao, Lu, Jianfeng, and Zhou, Jun

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning
Abstract

Denoising is a crucial preprocessing step for hyperspectral images (HSIs) due to noise arising from intra-imaging mechanisms and environmental factors. Long-range spatial-spectral correlation modeling is beneficial for HSI denoising but often comes with high computational complexity. Based on the state space model (SSM), Mamba is known for its remarkable long-range dependency modeling capabilities and computational efficiency. Building on this, we introduce a memory-efficient spatial-spectral UMamba (SSUMamba) for HSI denoising, with the spatial-spectral continuous scan (SSCS) Mamba being the core component. SSCS Mamba alternates the row, column, and band in six different orders to generate the sequence and uses the bidirectional SSM to exploit long-range spatial-spectral dependencies. In each order, the images are rearranged between adjacent scans to ensure spatial-spectral continuity. Additionally, 3D convolutions are embedded into the SSCS Mamba to enhance local spatial-spectral modeling. Experiments demonstrate that SSUMamba achieves superior denoising results with lower memory consumption per batch compared to transformer-based methods. The source code is available at https://github.com/lronkitty/SSUMamba.

Published
2024

2. Hyperspectral Image Denoising via Spatial-Spectral Recurrent Transformer

Author

Fu, Guanyiman, Xiong, Fengchao, Lu, Jianfeng, Zhou, Jun, Zhou, Jiantao, and Qian, Yuntao

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Hyperspectral images (HSIs) often suffer from noise arising from both intra-imaging mechanisms and environmental factors. Leveraging domain knowledge specific to HSIs, such as global spectral correlation (GSC) and non-local spatial self-similarity (NSS), is crucial for effective denoising. Existing methods tend to independently utilize each of these knowledge components with multiple blocks, overlooking the inherent 3D nature of HSIs where domain knowledge is strongly interlinked, resulting in suboptimal performance. To address this challenge, this paper introduces a spatial-spectral recurrent transformer U-Net (SSRT-UNet) for HSI denoising. The proposed SSRT-UNet integrates NSS and GSC properties within a single SSRT block. This block consists of a spatial branch and a spectral branch. The spectral branch employs a combination of transformer and recurrent neural network to perform recurrent computations across bands, allowing for GSC exploitation beyond a fixed number of bands. Concurrently, the spatial branch encodes NSS for each band by sharing keys and values with the spectral branch under the guidance of GSC. This interaction between the two branches enables the joint utilization of NSS and GSC, avoiding their independent treatment. Experimental results demonstrate that our method outperforms several alternative approaches. The source code will be available at https://github.com/lronkitty/SSRT.

Published
2023
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3. SMDS-Net: Model Guided Spectral-Spatial Network for Hyperspectral Image Denoising

Author

Xiong, Fengchao, Tao, Shuyin, Zhou, Jun, Lu, Jianfeng, Zhou, Jiantao, and Qian, Yuntao

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

Deep learning (DL) based hyperspectral images (HSIs) denoising approaches directly learn the nonlinear mapping between observed noisy images and underlying clean images. They normally do not consider the physical characteristics of HSIs, therefore making them lack of interpretability that is key to understand their denoising mechanism.. In order to tackle this problem, we introduce a novel model guided interpretable network for HSI denoising. Specifically, fully considering the spatial redundancy, spectral low-rankness and spectral-spatial properties of HSIs, we first establish a subspace based multi-dimensional sparse model. This model first projects the observed HSIs into a low-dimensional orthogonal subspace, and then represents the projected image with a multidimensional dictionary. After that, the model is unfolded into an end-to-end network named SMDS-Net whose fundamental modules are seamlessly connected with the denoising procedure and optimization of the model. This makes SMDS-Net convey clear physical meanings, i.e., learning the low-rankness and sparsity of HSIs. Finally, all key variables including dictionaries and thresholding parameters are obtained by the end-to-end training. Extensive experiments and comprehensive analysis confirm the denoising ability and interpretability of our method against the state-of-the-art HSI denoising methods., Comment: The experimental settings have been updated

Published
2020

6. Material Based Object Tracking in Hyperspectral Videos: Benchmark and Algorithms

Author

Xiong, Fengchao, Zhou, Jun, and Qian, Yuntao

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence
Abstract

Traditional color images only depict color intensities in red, green and blue channels, often making object trackers fail in challenging scenarios, e.g., background clutter and rapid changes of target appearance. Alternatively, material information of targets contained in a large amount of bands of hyperspectral images (HSI) is more robust to these difficult conditions. In this paper, we conduct a comprehensive study on how material information can be utilized to boost object tracking from three aspects: benchmark dataset, material feature representation and material based tracking. In terms of benchmark, we construct a dataset of fully-annotated videos, which contain both hyperspectral and color sequences of the same scene. Material information is represented by spectral-spatial histogram of multidimensional gradient, which describes the 3D local spectral-spatial structure in an HSI, and fractional abundances of constituted material components which encode the underlying material distribution. These two types of features are embedded into correlation filters, yielding material based tracking. Experimental results on the collected benchmark dataset show the potentials and advantages of material based object tracking., Comment: Update results

Published
2018

8. Object Tracking in Hyperspectral Videos with Convolutional Features and Kernelized Correlation Filter

Author

Qian, Kun, Zhou, Jun, Xiong, Fengchao, Zhou, Huixin, and Du, Juan

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Target tracking in hyperspectral videos is a new research topic. In this paper, a novel method based on convolutional network and Kernelized Correlation Filter (KCF) framework is presented for tracking objects of interest in hyperspectral videos. We extract a set of normalized three-dimensional cubes from the target region as fixed convolution filters which contain spectral information surrounding a target. The feature maps generated by convolutional operations are combined to form a three-dimensional representation of an object, thereby providing effective encoding of local spectral-spatial information. We show that a simple two-layer convolutional networks is sufficient to learn robust representations without the need of offline training with a large dataset. In the tracking step, KCF is adopted to distinguish targets from neighboring environment. Experimental results demonstrate that the proposed method performs well on sample hyperspectral videos, and outperforms several state-of-the-art methods tested on grayscale and color videos in the same scene., Comment: Accepted by ICSM 2018

Published
2018

16. Discriminative Vision Transformer for Heterogeneous Cross-Domain Hyperspectral Image Classification

Author

Ye, Minchao, Ling, Jiawei, Huo, Wanli, Zhang, Zhaojuan, Xiong, Fengchao, and Qian, Yuntao

Abstract

The transformer has been introduced in the hyperspectral image (HSI) classification, demonstrating outstanding capability in capturing global features compared to the convolutional neural network (CNN). However, the small-sample-size problem poses a significant challenge in practical HSI classification, especially in training the transformer. To tackle this issue, cross-domain transfer learning is adopted as a practical solution, which transfers the information from a source domain with abundant labeled samples to a target domain with limited labeled samples. This article proposes a novel transfer learning method for heterogeneous cross-domain HSI classification called cross-domain discriminative vision transformer (CD-DViT). This algorithm primarily contains three key contributions. First, source samples are mapped to the target domain through an encoder-decoder architecture, and the mapped source samples can be used to train the target classifier. Second, the cross-attention mechanism is utilized to construct two blocks for achieving the domainwise and classwise feature alignments (FAs), respectively. Specifically, the combination of the cross-attention mechanism with the domain discriminator aims to learn domain-invariant features, thereby facilitating domainwise alignment and alleviating domain shift. Third, knowledge distillation (KD) is adopted to learn more information from the target domain and assist in classifying target samples. Our experiments on three real-world cross-domain HSI datasets demonstrate the effectiveness of the proposed approach.

Published
2024
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17. Iterative Low-Rank Network for Hyperspectral Image Denoising

Author

Ye, Jin, Xiong, Fengchao, Zhou, Jun, and Qian, Yuntao

Abstract

Hyperspectral image (HSI) denoising is a crucial preprocessing step for subsequent tasks. The clean HSI usually reside in a low-dimensional subspace, which can be captured by low-rank and sparse representation, known as the physical prior of HSI. It is generally challenging to adequately use such physical properties for effective denoising while preserving image details. This article introduces a novel iterative low-rank network (ILRNet) to address these challenges. ILRNet integrates the strengths of model-driven and data-driven approaches by embedding a rank minimization module (RMM) within a U-Net architecture. This module transforms feature maps into the wavelet domain and applies singular value thresholding (SVT) to the low-frequency components during the forward pass, leveraging the spectral low-rankness of HSIs in the feature domain. The parameter, closely related to the hyperparameter of the singular vector thresholding algorithm, is adaptively learned from the data, allowing for flexible and effective capture of low-rankness across different scenarios. Additionally, ILRNet features an iterative refinement process that adaptively combines intermediate denoised HSIs with noisy inputs. This manner ensures progressive enhancement and superior preservation of image details. Experimental results demonstrate that ILRNet achieves state-of-the-art performance in both synthetic and real-world noise removal tasks.

Published
2024
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18. Wavelet Siamese Network With Semi-Supervised Domain Adaptation for Remote Sensing Image Change Detection

Author

Xiong, Fengchao, Li, Tianhan, Yang, Yi, Zhou, Jun, Lu, Jianfeng, and Qian, Yuntao

Abstract

Change detection is a crucial technique in remote sensing image analysis and faces challenges, such as background complexity and appearance shift, resulting in incomplete change boundaries and pseudochanges. This article introduces a novel wavelet Siamese network with semi-supervised domain adaptation (DA) to address these issues, named WS-Net++. WS-Net++ establishes spatial–frequency interactions between bitemporal images to enhance the completeness of the change boundaries. The spatial-domain interaction highlights the pixelwise differences. The frequency-domain interaction first adaptively adjusts the contributions from different frequency components based on image context. Within-frequency and between-frequency interactions are further constructed to capture the frequency-domain differences, enabling the adaptive and effective handling of both overall and subtle changes. In addition, WS-Net++ employs a semi-supervised DA strategy to mitigate the appearance shifts between bitemporal images. By categorizing regions into changed, unchanged, and regions of no interest in a semi-supervised manner, the network minimizes intraclass discrepancies within unchanged regions and maximizes interclass discrepancies between changed regions, reducing the domain gap. Experimental results on the LEVIR-CD, WHU-CD, and CLCD datasets demonstrate that our WS-Net++ outperforms alternative methods, achieving the $F1$ scores of 91.31%, 94.52%, and 79.77%, respectively. The code and models will be publicly available at https://github.com/JiTaiTai/WS-Net_Plus for reproducible research.

Published
2024
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38. Deep Parameterized Neural Networks for Hyperspectral Image Denoising

Author

Xiong, Fengchao, Zhou, Jun, Zhou, Jiantao, Lu, Jianfeng, and Qian, Yuntao

Abstract

Sparse representation (SR)-based hyperspectral image (HSI) denoising methods normally average the local denoising results of multiple overlapped cubes to recover the whole HSI. Though interpretable, they rely on cumbersome hyperparameter settings and ignore the relationship between overlapped cubes, leading to poor denoising performance. This article combines SR and convolutional neural networks and introduces a deep parameterized sparse neural network (DPNet-S) to address the above issues. DPNet-S parameterizes the SR-based HSI denoising model with two modules: 1) sparse optimizer to extract sparse feature maps from noisy HSIs via recurrent usage of convolution, deconvolution, and soft shrinkage operations; and 2) image reconstructor to recover the denoised HSI from its sparse feature maps via deconvolution operations. We further replace the soft shrinkage operator with U-Net architecture to account for general HSI priors and more effectively capture the complex structures of HSIs, resulting in DPNet-U. Both networks directly learn the parameters from data and perform denoising on the whole HSI, which overcomes the limitations of SR-based methods. Moreover, our networks are generated from the denoising model and optimization procedures, thus leveraging the knowledge embedded and relying less on the number of training samples. Extensive experiments on both synthetic and real-world HSIs show that our DPNet-S and DPNet-U achieve remarkable results when compared with state-of-the-art methods. The codes will be publicly available at https://github.com/bearshng/dpnets for reproducible research.

Published
2023
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