2008
DOI: 10.1109/tip.2008.2004797
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Complex Wavelet Bases, Steerability, and the Marr-Like Pyramid

Abstract: Abstract-Our aim in this paper is to tighten the link between wavelets, some classical image-processing operators, and David Marr's theory of early vision. The cornerstone of our approach is a new complex wavelet basis that behaves like a smoothed version of the Gradient-Laplace operator. Starting from first principles, we show that a single-generator wavelet can be defined analytically and that it yields a semi-orthogonal complex basis of , irrespective of the dilation matrix used. We also provide an efficien… Show more

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Cited by 35 publications
(27 citation statements)
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“…Moreover, yields a complex Riesz basis of provided that . Interestingly, these wavelets are special instances (up to some proportionality factor) of the complex rotation-covariant wavelets that we had identified and characterized mathematically in previous work [39], [40]. Our earlier formulation did not involve the Riesz transform but rather a combination of iterated Laplace and complex gradient (or Wirtinger) operators of the form (25) The link with (23) is obtained by making use of (14) which yields the equivalence with the case The advantage of the present formulation is that we have identified the unitary mapping that transforms the complex wavelets into the polyharmonic ones (and vice versa) which simplifies the theory considerably.…”
Section: E Complex Riesz-laplace Wavelet Basis Ofmentioning
confidence: 80%
“…Moreover, yields a complex Riesz basis of provided that . Interestingly, these wavelets are special instances (up to some proportionality factor) of the complex rotation-covariant wavelets that we had identified and characterized mathematically in previous work [39], [40]. Our earlier formulation did not involve the Riesz transform but rather a combination of iterated Laplace and complex gradient (or Wirtinger) operators of the form (25) The link with (23) is obtained by making use of (14) which yields the equivalence with the case The advantage of the present formulation is that we have identified the unitary mapping that transforms the complex wavelets into the polyharmonic ones (and vice versa) which simplifies the theory considerably.…”
Section: E Complex Riesz-laplace Wavelet Basis Ofmentioning
confidence: 80%
“…First, a multiscale primal sketch [14], or edge map [15], is extracted from the set of wavelet coefficients of the image. An approximation of the original image is then recovered from this small subset of coefficients relying on constrained optimization.…”
Section: B Image Reconstruction From Edgesmentioning
confidence: 99%
“…5.1.1] that yields a pair of x-and y-derivative wavelets. Edges in the multiscale gradient signal are then detected based on a wavelet-domain version of the Canny edge detector, which includes nonmaximum suppression and hysteresis thesholding [14]. Note that the Canny edge detector requires an estimation of the strength and orientation of the gradient for each point of the image, which is obtained by steering the gradient-like wavelets at every scale and location.…”
Section: B Image Reconstruction From Edgesmentioning
confidence: 99%
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“…Micchelli et al [34] proposed this construction for polyharmonic wavelets in any number of dimensions and for dyadic subsampling; these wavelets are related to the (iterated) Laplacian operator. This concept of wavelet design has also been generalized for almost any differential operator [35], including for Wirtinger-type operators [36], [37] and Riesz transforms [38].…”
Section: Theoremmentioning
confidence: 99%