Decoupling Degradations with Recurrent Network for Video Restoration in Under-Display Camera

ArXiv Pub Date : 2024-03-08 DOI:10.1609/aaai.v38i4.28144
Chengxu Liu, Xuan Wang, Yuanting Fan, Shuai Li, Xueming Qian
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Abstract

Under-display camera (UDC) systems are the foundation of full-screen display devices in which the lens mounts under the display. The pixel array of light-emitting diodes used for display diffracts and attenuates incident light, causing various degradations as the light intensity changes. Unlike general video restoration which recovers video by treating different degradation factors equally, video restoration for UDC systems is more challenging that concerns removing diverse degradation over time while preserving temporal consistency. In this paper, we introduce a novel video restoration network, called D2RNet, specifically designed for UDC systems. It employs a set of Decoupling Attention Modules (DAM) that effectively separate the various video degradation factors. More specifically, a soft mask generation function is proposed to formulate each frame into flare and haze based on the diffraction arising from incident light of different intensities, followed by the proposed flare and haze removal components that leverage long- and short-term feature learning to handle the respective degradations. Such a design offers an targeted and effective solution to eliminating various types of degradation in UDC systems. We further extend our design into multi-scale to overcome the scale-changing of degradation that often occur in long-range videos. To demonstrate the superiority of D2RNet, we propose a large-scale UDC video benchmark by gathering HDR videos and generating realistically degraded videos using the point spread function measured by a commercial UDC system. Extensive quantitative and qualitative evaluations demonstrate the superiority of D2RNet compared to other state-of-the-art video restoration and UDC image restoration methods.
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利用递归网络消除劣化,实现欠显示摄像机的视频修复
显示屏下摄像头(UDC)系统是全屏显示设备的基础,其中镜头安装在显示屏下。用于显示的发光二极管像素阵列会衍射和衰减入射光,从而随着光强的变化造成各种衰减。一般的视频修复是通过平等对待不同的劣化因素来恢复视频,与此不同,UDC 系统的视频修复更具挑战性,需要在保持时间一致性的同时消除随时间变化的各种劣化。本文介绍了一种专为 UDC 系统设计的新型视频修复网络,称为 D2RNet。它采用一组解耦注意力模块 (DAM),能有效分离各种视频劣化因素。更具体地说,它提出了一种软掩码生成功能,根据不同强度入射光产生的衍射,将每个帧划分为耀斑和雾霾,然后提出耀斑和雾霾去除组件,利用长期和短期特征学习来处理各自的劣化。这种设计为消除 UDC 系统中的各种劣化提供了有针对性的有效解决方案。我们进一步将设计扩展到多尺度,以克服长距离视频中经常出现的尺度变化退化。为了证明 D2RNet 的优越性,我们提出了一个大规模 UDC 视频基准,方法是收集 HDR 视频,并使用商业 UDC 系统测量的点扩散函数生成真实的降级视频。广泛的定量和定性评估表明,与其他最先进的视频修复和 UDC 图像修复方法相比,D2RNet 具有卓越的性能。
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