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Fusion of intensity and inter-component chromatic difference for effective and robust colour edge detection

Fusion of intensity and inter-component chromatic difference for effective and robust colour edge detection

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Edge detection, especially from colour images, plays very important roles in many applications for image analysis, segmentation and recognition. Most existing methods extract colour edges via fusing edges detected from each colour components or detecting from the intensity image where inter-component information is ignored. In this study, an improved method on colour edge detection is proposed in which the significant advantage is the use of inter-component difference information for effective colour edge detection. For any given colour image C, a grey D-image is defined as the accumulative differences between each of its two colour components, and another grey R-image is then obtained by weighting of D-image and the grey intensity image G. The final edges are determined through fusion of edges extracted from R-image and G-image. Quantitative evaluations under various levels of Gaussian noise are achieved for further comparisons. Comprehensive results from different test images have proved that this approach outperforms edges detected from traditional colour spaces like RGB, YCbCr and HSV in terms of effectiveness and robustness.

Inspec keywords: image colour analysis; image fusion; Gaussian noise; edge detection

Other keywords: colour edge detection; grey R-image; grey intensity G image; quantitative evaluations; Gaussian noise; intercomponent chromatic difference; grey D-image; image segmentation; image recognition; image analysis; intensity edge detection fusion

Subjects: Image recognition; Computer vision and image processing techniques

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