2000
DOI: 10.1109/83.846246
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Image enhancement by nonlinear extrapolation in frequency space

Abstract: A technique for enhancing the perceptual sharpness of an image is described. The enhancement algorithm augments the frequency content of the image using shape-invariant properties of edges across scale by using a nonlinearity that generates phase coherent higher harmonics. The procedure utilizes the Laplacian transform and the Laplacian pyramid image representation. Results are presented depicting the power-spectra augmentation and the visual enhancement of several images. Simplicity of computations and ease o… Show more

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Cited by 167 publications
(112 citation statements)
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“…Compared with the former segmentation algorithms this detection algorithm could not only extract edges of a target clearly but also the edges succession behaves better because of the "non-maximum restraint" for pixels gradient in course of optimization. From Fourier transformation frequency spectra Fig.3(a), Fig.3(b) and Fig.3(c) relative to Fig.2(b), Fig.2(c) and Fig.2(d) the effect of the Laplace-Gauss edge detection [7] could be evaluated. Their energy is basically along the main axis and lower inside quadrants with a great loss of details information.…”
Section: Experiments Results and Analysismentioning
confidence: 99%
“…Compared with the former segmentation algorithms this detection algorithm could not only extract edges of a target clearly but also the edges succession behaves better because of the "non-maximum restraint" for pixels gradient in course of optimization. From Fourier transformation frequency spectra Fig.3(a), Fig.3(b) and Fig.3(c) relative to Fig.2(b), Fig.2(c) and Fig.2(d) the effect of the Laplace-Gauss edge detection [7] could be evaluated. Their energy is basically along the main axis and lower inside quadrants with a great loss of details information.…”
Section: Experiments Results and Analysismentioning
confidence: 99%
“…1 we can find that the LP stages of a step signal have the similar structure, and the difference is only that the slope is different in the neighborhoods of the zero-crossing point. Therefore, we can predict the high frequency stage Ä ½ by changing the slope of the stage Ä ¼ near the zerocrossing point [8]- [11]. However, [8]- [11] are limited to the representation of the integer pyramid stages and only have the ability of expanding an image up by a factor of two in size.…”
Section: B "Zoom In" Methods Based On the Laplacian Pyramid Representmentioning
confidence: 99%
“…Therefore, we can predict the high frequency stage Ä ½ by changing the slope of the stage Ä ¼ near the zerocrossing point [8]- [11]. However, [8]- [11] are limited to the representation of the integer pyramid stages and only have the ability of expanding an image up by a factor of two in size. In many applications we also need arbitrary enlargement scales, such as 1.41 times and so on.…”
Section: B "Zoom In" Methods Based On the Laplacian Pyramid Representmentioning
confidence: 99%
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