Your search keyword '"Li, Jinxing"' showing total 7 results

1. Logical Relation Inference and Multiview Information Interaction for Domain Adaptation Person Re-Identification

Author

Li, Shuang, Li, Fan, Li, Jinxing, Li, Huafeng, Zhang, Bob, Tao, Dapeng, and Gao, Xinbo

Abstract

Domain adaptation person re-identification (Re-ID) is a challenging task, which aims to transfer the knowledge learned from the labeled source domain to the unlabeled target domain. Recently, some clustering-based domain adaptation Re-ID methods have achieved great success. However, these methods ignore the inferior influence on pseudo-label prediction due to the different camera styles. The reliability of the pseudo-label plays a key role in domain adaptation Re-ID, while the different camera styles bring great challenges for pseudo-label prediction. To this end, a novel method is proposed, which bridges the gap of different cameras and extracts more discriminative features from an image. Specifically, an intra-to-intermechanism is introduced, in which samples from their own cameras are first grouped and then aligned at the class level across different cameras followed by our logical relation inference (LRI). Thanks to these strategies, the logical relationship between simple classes and hard classes is justified, preventing sample loss caused by discarding the hard samples. Furthermore, we also present a multiview information interaction (MvII) module that takes features of different images from the same pedestrian as patch tokens, obtaining the global consistency of a pedestrian that contributes to the discriminative feature extraction. Unlike the existing clustering-based methods, our method employs a two-stage framework that generates reliable pseudo-labels from the views of the intracamera and intercamera, respectively, to differentiate the camera styles, subsequently increasing its robustness. Extensive experiments on several benchmark datasets show that the proposed method outperforms a wide range of state-of-the-art methods. The source code has been released at https://github.com/lhf12278/LRIMV.

Published

2024

2. Learning Context-Based Nonlocal Entropy Modeling for Image Compression

Author

Li, Mu, primary, Zhang, Kai, additional, Li, Jinxing, additional, Zuo, Wangmeng, additional, Timofte, Radu, additional, and Zhang, David, additional

Published

2023

3. Harmonization Shared Autoencoder Gaussian Process Latent Variable Model With Relaxed Hamming Distance

Author

Li, Jinxing, primary, Zhang, Bob, additional, Lu, Guangming, additional, Xu, Yong, additional, Wu, Feng, additional, and Zhang, David, additional

Published

2021

4. Relaxed Asymmetric Deep Hashing Learning: Point-to-Angle Matching

Author

Li, Jinxing, primary, Zhang, Bob, additional, Lu, Guangming, additional, You, Jane, additional, Xu, Yong, additional, Wu, Feng, additional, and Zhang, David, additional

Published

2020

5. SRGC-Nets: Sparse Repeated Group Convolutional Neural Networks

Author

Lu, Yao, primary, Lu, Guangming, additional, Lin, Rui, additional, Li, Jinxing, additional, and Zhang, David, additional

Published

2020

6. Shared Autoencoder Gaussian Process Latent Variable Model for Visual Classification

Author

Li, Jinxing, primary, Zhang, Bob, additional, and Zhang, David, additional

Published

2018

7. Focus Affinity Perception and Super-Resolution Embedding for Multifocus Image Fusion.

Author

Li H, Yuan M, Li J, Liu Y, Lu G, Xu Y, Yu Z, and Zhang D

Abstract

Despite the fact that there is a remarkable achievement on multifocus image fusion, most of the existing methods only generate a low-resolution image if the given source images suffer from low resolution. Obviously, a naive strategy is to independently conduct image fusion and image super-resolution. However, this two-step approach would inevitably introduce and enlarge artifacts in the final result if the result from the first step meets artifacts. To address this problem, in this article, we propose a novel method to simultaneously achieve image fusion and super-resolution in one framework, avoiding step-by-step processing of fusion and super-resolution. Since a small receptive field can discriminate the focusing characteristics of pixels in detailed regions, while a large receptive field is more robust to pixels in smooth regions, a subnetwork is first proposed to compute the affinity of features under different types of receptive fields, efficiently increasing the discriminability of focused pixels. Simultaneously, in order to prevent from distortion, a gradient embedding-based super-resolution subnetwork is also proposed, in which the features from the shallow layer, the deep layer, and the gradient map are jointly taken into account, allowing us to get an upsampled image with high resolution. Compared with the existing methods, which implemented fusion and super-resolution independently, our proposed method directly achieves these two tasks in a parallel way, avoiding artifacts caused by the inferior output of image fusion or super-resolution. Experiments conducted on the real-world dataset substantiate the superiority of our proposed method compared with state of the arts.

Published

2024