Abstract
Feature point detection is the basis of computer vision, and the detection methods with geometric invariance and illumination invariance are the key and difficult problem in the field of feature detection. This paper proposes an illumination-invariant feature point detection method based on neighborhood information. The method can be summarized into two steps. Firstly, the feature points are divided into eight types according to the number of connected neighbors. Secondly, each type of feature points is classified again according to the position distribution of neighboring pixels. The theoretical deduction proves that the proposed method has lower computational complexity than other methods. The experimental results indicate that, when the photometric variation of the two images is very large, the feature-based detection methods are usually inferior, while the learning-based detection methods performs better. However, our method performs better than the learning-based detection method in terms of the number of feature points, the number of matching points, and the repeatability rate stability. The experimental results demonstrate that the proposed method has the best illumination robustness among state-of-the-art feature detection methods.
Highlights
Digital images consist of limited and discrete pixels obtained using digital image sensors
This paper focuses on the feature point detection method of illumination robustness, proposes a novel method of illumination-robust feature point detection
This paper proposes a novel feature point detection method based on the position of the neighborhood connection
Summary
Digital images consist of limited and discrete pixels obtained using digital image sensors (such as CCD or CMOS). These discrete pixels reflect energy intensity through numerical values, and the energy intensity is related to the characteristics of the captured object. Feature detection is an abstraction of image information and a local decision-making method for each pixel whether there is a given type of feature. It is a fundamental problem in computer vision and has many practical applications, such as object detection [1], stereo matching [2], color matching [3], and motion estimation [4]. In order to response to diverse applications, many detection methods have been
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