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http://dx.doi.org/10.9718/JBER.2008.29.2.122

Speckle Noise Reduction and Edge Enhancement in Ultrasound Images Based on Wavelet Transform  

Kim, Yong-Sun (School of Electrical Engineering & Computer Science, Korea Advanced Institute of Science and Technology)
Ra, Jong-Beom (School of Electrical Engineering & Computer Science, Korea Advanced Institute of Science and Technology)
Publication Information
Journal of Biomedical Engineering Research / v.29, no.2, 2008 , pp. 122-131 More about this Journal
Abstract
For B-mode ultrasound images, we propose an image enhancement algorithm based on a multi-resolution approach, which consists of edge enhancing and noise reducing procedures. Edge enhancement processing is applied sequentially to coarse-to-fine resolution images obtained from wavelet-transformed data. In each resolution, the structural features of each pixel are examined through eigen analysis. Then, if a pixel belongs to an edge region, we perform two-step filtering: that is, directional smoothing is conducted along the tangential direction of the edge to improve continuity and directional sharpening is conducted along the normal direction to enhance the contrast. In addition, speckle noise is alleviated by proper attenuation of the wavelet coefficients of the homogeneous regions at each band. This region-based speckle-reduction scheme is differentiated from other methods that are based on the magnitude statistics of the wavelet coefficients. The proposed algorithm enhances edges regardless of changes in the resolution of an image, and the algorithm efficiently reduces speckle noise without affecting the sharpness of the edge. Hence, compared with existing algorithms, the proposed algorithm considerably improves the subjective image quality without providing any noticeable artifacts.
Keywords
ultrasound image enhancement; speckle-noise reduction; wavelet transform; eigen analysis; directional filtering;
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