Driving in the Rain: A Survey toward Visibility Estimation through Windshields

We propose a novel model‐free unsupervised learning paradigm to tackle the unfavorable prevailing problem of real‐world image deraining, dubbed MUL‐Derain. Beyond existing unsupervised deraining efforts, MUL‐Derain leverages a model‐free Multiscale Attentive Filtering (MSAF) to handle multiscale rain streaks. Therefore, formulation of any rain imaging is not necessary, and it requires neither iterative optimization nor progressive refinement operations. Meanwhile, MUL‐Derain can efficiently compute spatial coherence and global interactions by modeling long‐range dependencies, allowing MSAF to learn useful knowledge from a larger or even global rain region. Furthermore, we formulate a novel multiloss function to constrain MUL‐Derain to preserve both color and structure information from the rainy images. Extensive experiments on both synthetic and real‐world datasets demonstrate that our MUL‐Derain obtains state‐of‐the‐art performance over un/semisupervised methods and exhibits competitive advantages over the fully‐supervised ones.

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An Investigation of ADAS Camera Performance Degradation Using a Realistic Rain Simulation System in Wind Tunnel

Li,

Pao,

Howorth

et al. 2024

SAE Technical Paper Series

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<div class="section abstract"><div class="htmlview paragraph">Modern advances in the technical developments of Advanced Driver Assistance Systems (ADAS) have elevated autonomous vehicle (AV) operations to a new height. Vehicles equipped with sensor based ADAS have been positively contributing to safer roads. As the automotive industry strives for SAE Level 5 full driving autonomy, challenges inevitably arise to ensure ADAS performance and reliability in all driving scenarios, especially in adverse weather conditions, during which ADAS sensors such as optical cameras and LiDARs suffer performance degradation, leading to inaccuracy and inability to provide crucial environmental information for object detection. Currently, the difficulty to simulate realistic and dynamic adverse weather scenarios experienced by vehicles in a controlled environment becomes one of the challenges that hinders further ADAS development. While outdoor testing encounters unpredictable environmental variables, indoor testing methods, such as using spray nozzles in a wind tunnel, are often unrealistic due to the atomization of the spray droplets, causing the droplet size distributions to deviate from real-life conditions. A novel full-scale rain simulation system is developed and implemented into the ACE Climatic Aerodynamic Wind Tunnel at Ontario Tech University with the goal of quantifying ADAS sensor performance when driving in rain. The designed system is capable of recreating a wide range of dynamic rain intensity experienced by the vehicle at different driving speeds, along with the corresponding droplet size distributions. Proposed methods to evaluate optical cameras are discussed, with sample results of object detection performance and image evaluation metrics presented. Additionally, the rain simulation system showcases repeatable testing environments for soiling mitigation developments. It also demonstrates the potential to further broaden the scope of testing, such as training object detection datasets, as well as exploring the possibilities of using artificial intelligence to expand and predict the rain system control strategies and target rain conditions.</div></div>

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Driving in the Rain: A Survey toward Visibility Estimation through Windshields

Cited by 3 publications

References 69 publications

Exploring Arduino based Electronic Circuit Design: A Study of Innovative Applications and Prototypes

Exploring Arduino based Electronic Circuit Design: A Study of Innovative Applications and Prototypes

Real‐World Image Deraining Using Model‐Free Unsupervised Learning

An Investigation of ADAS Camera Performance Degradation Using a Realistic Rain Simulation System in Wind Tunnel

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