Abstract
The recently proposed multi-objective clustering methods convert the segmentation problem to a multi-objective optimization problem by extracting multiple features from an image to be segmented as clustering data. However, most of these methods fail to consider the impacts of different features on segmentation results when calculating the similarity using the Euclidean distance. In this paper, feature domination is defined to segment the image efficiently, and then an adaptive feature weights based double-layer multi-objective method (AFWDLMO) for image segmentation is presented. The proposed method mainly contains two layers: a weight determination layer and a clustering layer. In the weight determination layer, AFWDLMO adaptively identifies the dominant feature of an image to be segmented and specifies its optimal weight through differential evolution. In the clustering layer, multi-objective clustering functions are established and optimized based on the acquired optimal weight, and a set of solutions with high segmentation accuracy is found. The segmentation results on several texture images and SAR images show that the proposed method is better than several existing state-of-the-art segmentation algorithms.
Highlights
Synthetic aperture radar (SAR) is widely applied to many practical applications, such as environmental surveillance, natural disaster monitoring, land resources management, and target detection, which is an advanced active coherent microwave imaging mechanism to produce high-precision images and allows all-day and all-weather acquisitions [1,2].These applications involve extraction, recognition, understanding, and analysis of SAR images in the field of computer vision
Due to the coherent imaging mechanism of SAR, SAR images are susceptible to speckle noise, which reduces the quality of SAR images and harms segmentation performance
A two-layer framework is introduced for SAR image segmentation
Summary
Synthetic aperture radar (SAR) is widely applied to many practical applications, such as environmental surveillance, natural disaster monitoring, land resources management, and target detection, which is an advanced active coherent microwave imaging mechanism to produce high-precision images and allows all-day and all-weather acquisitions [1,2]. These applications involve extraction, recognition, understanding, and analysis of SAR images in the field of computer vision. The fuzzy theory is incorporated into clustering algorithms to retain as much information from the original image as possible. Fuzzy c-means (FCM) [4]
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