Your search keyword '"Yang, Wenhan"' showing total 12 results

1. Unsupervised Illumination Adaptation for Low-Light Vision

Author

Wang, Wenjing, Luo, Rundong, Yang, Wenhan, and Liu, Jiaying

Abstract

Insufficient lighting poses challenges to both human and machine visual analytics. While existing low-light enhancement methods prioritize human visual perception, they often neglect machine vision and high-level semantics. In this paper, we make pioneering efforts to build an illumination enhancement model for high-level vision. Drawing inspiration from camera response functions, our model could enhance images from the machine vision perspective despite being lightweight in architecture and simple in formulation. We also introduce two approaches that leverage knowledge from base enhancement curves and self-supervised pretext tasks to train for different downstream normal-to-low-light adaptation scenarios. Our proposed framework overcomes the limitations of existing algorithms without requiring access to labeled data in low-light conditions. It facilitates more effective illumination restoration and feature alignment, significantly improving the performance of downstream tasks in a plug-and-play manner. This research advances the field of low-light machine analytics and broadly applies to various high-level vision tasks, including classification, face detection, optical flow estimation, and video action recognition.

Published

2024

2. Video Coding for Machines: Compact Visual Representation Compression for Intelligent Collaborative Analytics

Author

Yang, Wenhan, primary, Huang, Haofeng, additional, Hu, Yueyu, additional, Duan, Ling-Yu, additional, and Liu, Jiaying, additional

Published

2024

3. Learning to Remove Rain in Video With Self-Supervision

Author

Yang, Wenhan, Tan, Robby T., Wang, Shiqi, Kot, Alex C., and Liu, Jiaying

Abstract

In heavy rain video, rain streak and rain accumulation are the most common causes of degradation. They occlude background information and can significantly impair the visibility. Most existing methods rely heavily on the synthetic training data, and thus raise the domain gap problem that prevents the trained models from performing adequately in real testing cases. Unlike these methods, we introduce a self-learning method to remove both rain streaks and rain accumulation without using any ground-truth clean images in training our model, which consequently can alleviate the domain gap issue. The main idea is based on the assumptions that (1) adjacent clean frames can be aligned or warped from one frame to another frame, (2) rain streaks are distributed randomly in the temporal domain, (3) the rain streak/accumulation related variables/priors can be inferred reliably from the information within the images/sequences. Based on these assumptions, we construct an augmented Self-Learned Deraining Network (SLDNet+) to remove both rain streaks and rain accumulation by utilizing temporal correlation, consistency, and rain-related priors. For the temporal correlation, our SLDNet+ takes rain degraded adjacent frames as its input, aligns them, and learns to predict the clean version of the current frame. For the temporal consistency, a new loss is designed to build a robust mapping between the predicted clean frame and non-rain regions from the adjacent rain frames. For the rain-streak-related prior, the rain streak removal network is optimized jointly with motion estimation and rain region detection; while for the rain-accumulation-related prior, a novel non-local video rain accumulation removal method is developed to estimate the accumulation-lines from the whole input video and to offer better color constancy and temporal smoothness. Extensive experiments show the effectiveness of our approach, which provides superior results compared with the existing state of the art methods both quantitatively and qualitatively. The source code will be made publicly available at: https://github.com/flyywh/CVPR-2020-Self-Rain-Removal-Journal.

Published

2024

4. Unsupervised Face Detection in the Dark

Author

Wang, Wenjing, primary, Wang, Xinhao, additional, Yang, Wenhan, additional, and Liu, Jiaying, additional

Published

2023

5. Learning to Remove Rain in Video With Self-Supervision

Author

Yang, Wenhan, primary, Tan, Robby T., additional, Wang, Shiqi, additional, Kot, Alex C., additional, and Liu, Jiaying, additional

Published

2022

6. Bridging the Gap Between Computational Photography and Visual Recognition

Author

VidalMata, Rosaura G., primary, Banerjee, Sreya, additional, RichardWebster, Brandon, additional, Albright, Michael, additional, Davalos, Pedro, additional, McCloskey, Scott, additional, Miller, Ben, additional, Tambo, Asong, additional, Ghosh, Sushobhan, additional, Nagesh, Sudarshan, additional, Yuan, Ye, additional, Hu, Yueyu, additional, Wu, Junru, additional, Yang, Wenhan, additional, Zhang, Xiaoshuai, additional, Liu, Jiaying, additional, Wang, Zhangyang, additional, Chen, Hwann-Tzong, additional, Huang, Tzu-Wei, additional, Chin, Wen-Chi, additional, Li, Yi-Chun, additional, Lababidi, Mahmoud, additional, Otto, Charles, additional, and Scheirer, Walter J., additional

Published

2021

7. Single Image Deraining: From Model-Based to Data-Driven and Beyond

Author

Yang, Wenhan, primary, Tan, Robby T., additional, Wang, Shiqi, additional, Fang, Yuming, additional, and Liu, Jiaying, additional

Published

2021

8. Recurrent Multi-Frame Deraining: Combining Physics Guidance and Adversarial Learning

Author

Yang, Wenhan, primary, Tan, Robby T., additional, Feng, Jiashi, additional, Wang, Shiqi, additional, Cheng, Bin, additional, and Liu, Jiaying, additional

Published

2021

9. Learning End-to-End Lossy Image Compression: A Benchmark

Author

Hu, Yueyu, primary, Yang, Wenhan, additional, Ma, Zhan, additional, and Liu, Jiaying, additional

Published

2021

10. Joint Rain Detection and Removal from a Single Image with Contextualized Deep Networks

Author

Yang, Wenhan, primary, Tan, Robby T., additional, Feng, Jiashi, additional, Guo, Zongming, additional, Yan, Shuicheng, additional, and Liu, Jiaying, additional

Published

2020

11. Recurrent Multi-Frame Deraining: Combining Physics Guidance and Adversarial Learning.

Author

Yang W, Tan RT, Feng J, Wang S, Cheng B, and Liu J

Abstract

Existing video rain removal methods mainly focus on rain streak removal and are solely trained based on the synthetic data, which neglect more complex degradation factors, e.g., rain accumulation, and the prior knowledge in real rain data. Thus, in this paper, we build a more comprehensive rain model with several degradation factors and construct a novel two-stage video rain removal method that combines the power of synthetic videos and real data. Specifically, a novel two-stage progressive network is proposed: recovery guided by a physics model, and further restoration by adversarial learning. The first stage performs an inverse recovery process guided by our proposed rain model. An initially estimated background frame is obtained based on the input rain frame. The second stage employs adversarial learning to refine the result, i.e., recovering the overall color and illumination distributions of the frame, the background details that are failed to be recovered in the first stage, and removing the artifacts generated in the first stage. Furthermore, we also introduce a more comprehensive rain model that includes degradation factors, e.g., occlusion and rain accumulation, which appear in real scenes yet ignored by existing methods. This model, which generates more realistic rain images, will train and evaluate our models better. Extensive evaluations on synthetic and real videos show the effectiveness of our method in comparisons to the state-of-the-art methods. Our datasets, results and code are available at: https://github.com/flyywh/Recurrent-Multi-Frame-Deraining.

Published

2022

12. Learning End-to-End Lossy Image Compression: A Benchmark.

Author

Hu Y, Yang W, Ma Z, and Liu J

Abstract

Image compression is one of the most fundamental techniques and commonly used applications in the image and video processing field. Earlier methods built a well-designed pipeline, and efforts were made to improve all modules of the pipeline by handcrafted tuning. Later, tremendous contributions were made, especially when data-driven methods revitalized the domain with their excellent modeling capacities and flexibility in incorporating newly designed modules and constraints. Despite great progress, a systematic benchmark and comprehensive analysis of end-to-end learned image compression methods are lacking. In this paper, we first conduct a comprehensive literature survey of learned image compression methods. The literature is organized based on several aspects to jointly optimize the rate-distortion performance with a neural network, i.e., network architecture, entropy model and rate control. We describe milestones in cutting-edge learned image-compression methods, review a broad range of existing works, and provide insights into their historical development routes. With this survey, the main challenges of image compression methods are revealed, along with opportunities to address the related issues with recent advanced learning methods. This analysis provides an opportunity to take a further step towards higher-efficiency image compression. By introducing a coarse-to-fine hyperprior model for entropy estimation and signal reconstruction, we achieve improved rate-distortion performance, especially on high-resolution images. Extensive benchmark experiments demonstrate the superiority of our model in rate-distortion performance and time complexity on multi-core CPUs and GPUs.

Published

2022