Ship Detection in High-Resolution Optical Imagery Based on Anomaly Detector and Local Shape Feature
Ship detection in high-resolution optical imagery is a challenging task due to the variable appearances of ships and background. This paper aims at further investigating this problem and presents an approach to detect ships in a "coarse-to-fine" manner. First, to increase the separability...
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| Veröffentlicht in: | IEEE transactions on geoscience and remote sensing 2014-08, Vol.52 (8), p.4511-4523 |
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| creator | Shi, Zhenwei Yu, Xinran Jiang, Zhiguo Li, Bo |
| description | Ship detection in high-resolution optical imagery is a challenging task due to the variable appearances of ships and background. This paper aims at further investigating this problem and presents an approach to detect ships in a "coarse-to-fine" manner. First, to increase the separability between ships and background, we concentrate on the pixels in the vicinities of ships. We rearrange the spatially adjacent pixels into a vector, transforming the panchromatic image into a "fake" hyperspectral form. Through this procedure, each produced vector is endowed with some contextual information, which amplifies the separability between ships and background. Afterward, for the "fake" hyperspectral image, a hyperspectral algorithm is applied to extract ship candidates preliminarily and quickly by regarding ships as anomalies. Finally, to validate real ships out of ship candidates, an extra feature is provided with histograms of oriented gradients (HOGs) to generate a hypothesis using AdaBoost algorithm. This extra feature focuses on the gray values rather than the gradients of an image and includes some information generated by very near but not closely adjacent pixels, which can reinforce HOG to some degree. Experimental results on real database indicate that the hyperspectral algorithm is robust, even for the ships with low contrast. In addition, in terms of the shape of ships, the extended HOG feature turns out to be better than HOG itself as well as some other features such as local binary pattern. |
| doi_str_mv | 10.1109/TGRS.2013.2282355 |
| format | Article |
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This paper aims at further investigating this problem and presents an approach to detect ships in a "coarse-to-fine" manner. First, to increase the separability between ships and background, we concentrate on the pixels in the vicinities of ships. We rearrange the spatially adjacent pixels into a vector, transforming the panchromatic image into a "fake" hyperspectral form. Through this procedure, each produced vector is endowed with some contextual information, which amplifies the separability between ships and background. Afterward, for the "fake" hyperspectral image, a hyperspectral algorithm is applied to extract ship candidates preliminarily and quickly by regarding ships as anomalies. Finally, to validate real ships out of ship candidates, an extra feature is provided with histograms of oriented gradients (HOGs) to generate a hypothesis using AdaBoost algorithm. This extra feature focuses on the gray values rather than the gradients of an image and includes some information generated by very near but not closely adjacent pixels, which can reinforce HOG to some degree. Experimental results on real database indicate that the hyperspectral algorithm is robust, even for the ships with low contrast. 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This paper aims at further investigating this problem and presents an approach to detect ships in a "coarse-to-fine" manner. First, to increase the separability between ships and background, we concentrate on the pixels in the vicinities of ships. We rearrange the spatially adjacent pixels into a vector, transforming the panchromatic image into a "fake" hyperspectral form. Through this procedure, each produced vector is endowed with some contextual information, which amplifies the separability between ships and background. Afterward, for the "fake" hyperspectral image, a hyperspectral algorithm is applied to extract ship candidates preliminarily and quickly by regarding ships as anomalies. Finally, to validate real ships out of ship candidates, an extra feature is provided with histograms of oriented gradients (HOGs) to generate a hypothesis using AdaBoost algorithm. 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| subjects | "Reed-Xiaoli" algorithm Algorithms Anomalies Applied geophysics Circle frequency-histograms of oriented gradients (CF-HOG) feature Detectors Earth sciences Earth, ocean, space Exact sciences and technology Feature extraction Hyperspectral imaging Imagery Internal geophysics Marine vehicles Mathematical analysis Optical imaging optical panchromatic image analysis Pixels ship detection Ships Vectors Vectors (mathematics) |
| title | Ship Detection in High-Resolution Optical Imagery Based on Anomaly Detector and Local Shape Feature |
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