Abstract
Image enhancement is considered to be one of the complex tasks in image processing. When the images are captured under dim light, the quality of the images degrades due to low visibility degenerating the vision-based algorithms’ performance that is built for very good quality images with better visibility. After the emergence of a deep neural network number of methods has been put forward to improve images captured under low light. But, the results shown by existing low-light enhancement methods are not satisfactory because of the lack of effective network structures. A low-light image enhancement technique (LIMET) with a fine-tuned conditional generative adversarial network is presented in this paper. The proposed approach employs two discriminators to acquire a semantic meaning that imposes the obtained results to be realistic and natural. Finally, the proposed approach is evaluated with benchmark datasets. The experimental results highlight that the presented approach attains state-of-the-performance when compared to existing methods. The models’ performance is assessed using Visual Information Fidelitysse, which assesses the generated image’s quality over the degraded input. VIF obtained for different datasets using the proposed approach are 0.709123 for LIME dataset, 0.849982 for DICM dataset, 0.619342 for MEF dataset.
Highlights
Cameras are crucial in capturing real-world happenings in several accomplishments like remote sensing, autonomous driving solutions, and surveillance systems
The image pairs in the low-light dataset (LOL) dataset are synthesized on real scenes
The results generated from light image enhancement technique (LIMET) for low-light image enhancement are compared with several exisiting state-of-theart methods
Summary
Cameras are crucial in capturing real-world happenings in several accomplishments like remote sensing, autonomous driving solutions, and surveillance systems. Computer vision algorithms used for these applications require the images to be high visibility to achieve commendable performance (Lore et al, 2017). The quality of the images captured is greatly affected by the amount of light received by the camera’s sensor. The low-light images are prone to have additional noise (Wang et al, 2020). High-quality images cannot be obtained under low-light conditions that affect the performance of computer vision applications like object detection, recognition, segmentation and classification (Ai and Kwon, 2020). Developing a low-light image enhancement technique is essential to perform subsequent high-level computer vision tasks with ease and high accuracy.
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