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Projects > ELECTRONICS > 2018 > IEEE > DIGITAL IMAGE PROCESSING
The retinal vessel is one of the determining factors in an ophthalmic examination. Automatic extraction of retinal vessels from low-quality retinal images still remains a challenging problem. In this paper, we propose a robust and effective approach that qualitatively improves the detection of low-contrast and narrow vessels. Rather than using the pixel grid, we use a superpixel as the elementary unit of our vessel segmentation scheme. We regularize this scheme by combining the geometrical structure, texture, color, and space information in the superpixel graph. And the segmentation results are then refined by employing the efficient minimum spanning superpixel tree to detect and capture both global and local structure of the retinal images. Such an effective and structure-aware tree detector significantly improves the detection around the pathologic area. Experimental results have shown that the proposed technique achieves advantageous connectivity-area-length (CAL) scores of 80.92% and 69.06% on two public datasets, namely, DRIVE and STARE, thereby outperforming state-of-the-art segmentation methods. In addition, the tests on the challenging retinal image database have further demonstrated the effectiveness of our method. Our approach achieves satisfactory segmentation performance in comparison with state-of-the-art methods. Our technique provides an automated method for effectively extracting the vessel from fundus images.
Matched filter (MF), locally adaptive derivative frame
The main contribution of this paper is a novel superpixel-based vessel tree detector framework with the following unique characteristics. 1) It combines the superpixel and minimum spanning tree to segment retinal vessel. 2) It effectively addresses the detection of narrow and low contrast vessels, preventing influences from other retinal structures. 3) It achieves satisfactory segmentation performance in comparison with state-of-the-art methods. 4) The framework could be extended to human ID, as the retinal vessel structure is unique to each person.
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