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http://dx.doi.org/10.11108/kagis.2019.22.3.082

Detection Ability of Occlusion Object in Deep Learning Algorithm depending on Image Qualities  

LEE, Jeong-Min (Research Institute, Shinhan Aerial Survey CO., LTD)
HAM, Geon-Woo (Research Institute, Shinhan Aerial Survey CO., LTD)
BAE, Kyoung-Ho (Research Institute, Shinhan Aerial Survey CO., LTD)
PARK, Hong-Ki (Gachon university)
Publication Information
Journal of the Korean Association of Geographic Information Studies / v.22, no.3, 2019 , pp. 82-98 More about this Journal
Abstract
The importance of spatial information is rapidly rising. In particular, 3D spatial information construction and modeling for Real World Objects, such as smart cities and digital twins, has become an important core technology. The constructed 3D spatial information is used in various fields such as land management, landscape analysis, environment and welfare service. Three-dimensional modeling with image has the hig visibility and reality of objects by generating texturing. However, some texturing might have occlusion area inevitably generated due to physical deposits such as roadside trees, adjacent objects, vehicles, banners, etc. at the time of acquiring image Such occlusion area is a major cause of the deterioration of reality and accuracy of the constructed 3D modeling. Various studies have been conducted to solve the occlusion area. Recently the researches of deep learning algorithm have been conducted for detecting and resolving the occlusion area. For deep learning algorithm, sufficient training data is required, and the collected training data quality directly affects the performance and the result of the deep learning. Therefore, this study analyzed the ability of detecting the occlusion area of the image using various image quality to verify the performance and the result of deep learning according to the quality of the learning data. An image containing an object that causes occlusion is generated for each artificial and quantified image quality and applied to the implemented deep learning algorithm. The study found that the image quality for adjusting brightness was lower at 0.56 detection ratio for brighter images and that the image quality for pixel size and artificial noise control decreased rapidly from images adjusted from the main image to the middle level. In the F-measure performance evaluation method, the change in noise-controlled image resolution was the highest at 0.53 points. The ability to detect occlusion zones by image quality will be used as a valuable criterion for actual application of deep learning in the future. In the acquiring image, it is expected to contribute a lot to the practical application of deep learning by providing a certain level of image acquisition.
Keywords
Deep Learning; 3D Modeling; Texturing; Image Quality; Occlusion Area;
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Times Cited By KSCI : 1  (Citation Analysis)
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