Learning to Control Camera Exposure via Reinforcement Learning

Kyunghyun Lee, Ukcheol Shin, Byeong-Uk Lee; Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), 2024, pp. 2975-2983

Adjusting camera exposure in arbitrary lighting conditions is the first step to ensure the functionality of computer vision applications. Poorly adjusted camera exposure often leads to critical failure and performance degradation. Traditional camera exposure control methods require multiple convergence steps and time-consuming processes making them unsuitable for dynamic lighting conditions. In this paper we propose a new camera exposure control framework that rapidly controls camera exposure while performing real-time processing by exploiting deep reinforcement learning. The proposed framework consists of four contributions: 1) a simplified training ground to simulate real-world's diverse and dynamic lighting changes 2) flickering and image attribute-aware reward design along with lightweight state design for real-time processing 3) a static-to-dynamic lighting curriculum to gradually improve the agent's exposure-adjusting capability and 4) domain randomization techniques to alleviate the limitation of the training ground and achieve seamless generalization in the wild. As a result our proposed method rapidly reaches a desired exposure level within five steps with real-time processing (1 ms). Also the acquired images are well-exposed and show superiority in various computer vision tasks such as feature extraction and object detection.