A Computational Approach to Edge Detection
IEEE Transactions on Pattern Analysis and Machine Intelligence
Introduction to statistical pattern recognition (2nd ed.)
Introduction to statistical pattern recognition (2nd ed.)
Self-organizing maps
Modern Information Retrieval
Fuzzy Models and Algorithms for Pattern Recognition and Image Processing
Fuzzy Models and Algorithms for Pattern Recognition and Image Processing
An Affine Invariant Interest Point Detector
ECCV '02 Proceedings of the 7th European Conference on Computer Vision-Part I
Distinctive Image Features from Scale-Invariant Keypoints
International Journal of Computer Vision
A Comparison of Affine Region Detectors
International Journal of Computer Vision
Generating fuzzy membership function with self-organizing feature map
Pattern Recognition Letters
Overview of the ImageCLEFmed 2007 Medical Retrieval and Medical Annotation Tasks
Advances in Multilingual and Multimodal Information Retrieval
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This paper presents an approach to biomedical image retrieval by detecting affine covariant regions and representing them with an invariant fuzzy feature space. These regions refer to a set of pixels or interest points which change covariantly with a class of transformations, such as affinity. A vector descriptor based on Scale-Invariant Feature Transform (SIFT) computed from the intensity pattern within the region. These features are then vector quantized to build a codebbok of keypoints. By mapping the interest points extracted from one image to the keypoints in the codebook, their occurrences are counted and the resulting histogram is called the "bag of keypoints" for that image. Images are finally represented in fuzzy feature space by spreading each region's membership values through a global fuzzy membership function to all the keypoints in the codebook. The proposed feature extraction and representation scheme is not only invariant to affine transformations but also robust against quantization errors. A systematic evaluation of retrieval results on a heterogeneous medical image collection has shown around 15-20% improvement in precision at different recall levels for the proposed fuzzy feature-based representation when compared to individual color, texture, edge, and keypoint-based features.