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Image Feature Point Detection and Matching Method Based on Maximum Image Entropy Gamma Correction Estimation |
YUAN Chao1,ZHAO Yadong1,ZHANG Yao1, XU Dawei1,2,YUAN Jing3,ZHAI Yongjie1 |
1. Department of Automation, North China Electric Power University, Baoding, Hebei 071033, China
2. The State Key Laboratory for Management & Control of Complex Systems, Institute of Automation Chinese Academy of Sciences, Beijing 100190, China
3. College of Artificial Intelligence, Nankai University, Tianjin 300071, China |
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Abstract When the ambient lighting of the captured image is low or high, it will result in low contrast of the image, which will bring great difficulties in feature point detection and matching. To solve this problem, An image feature point detection and matching method based on maximum image entropy Gamma correction estimation is proposed. The contrast of the image is enhanced by a preprocessing algorithm, which is applied to the detection and matching of image feature points. In the preprocessing stage, the image is first normalized using a logarithmic function, and divided into bright and dark components according to a set threshold; then different parameters are adaptively selected for Gamma correction for the two components respectively, and the correction parameter that maximizes its entropy is determined to be the optimal parameter for each component; finally, the above parameters are applied to Gamma correction to generate a corrected map that corresponds to the original image bright and dark regions, and fusion is performed. Finally, the above parameters are applied to the Gamma correction to generate the corrected maps corresponding to the bright and dark regions of the original image, and fused to generate the enhanced image. The pre-processed image is subjected to feature point detection and matching experiments. The results show that compared with the unprocessed algorithm, HE algorithm and adaptive Gamma algorithm, the number of matches after feature point detection is increased by 85.7%, 26.4% and 15.2% on dark images, and 59.4%, 12.2% and 103.8% on bright images, respectively, and the matching effect is significantly improved.
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Received: 05 July 2023
Published: 23 May 2024
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