Morphological PDE and Dilation/Erosion Semigroups on Length Spaces

Angulo, Jesús

doi:10.1007/978-3-319-18720-4_43

Cited by 4 publications

(4 citation statements)

References 28 publications

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“…For the application of the latter model to adaptive morphology, see [15]. In the most general case, this family of morphological PDEs and semigroups are formulated in the framework of length spaces [5] and a similar counterpart in ultrametric spaces [6]. A general theory of morphological counterparts of linear shift-invariant scalespaces based on the Cramér-Fourier transform has been proposed [24].…”

Section: Introductionmentioning

confidence: 99%

Morphological Counterpart of Ornstein–Uhlenbeck Semigroups and PDEs

Angulo

2022

Lecture Notes in Computer Science

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Morphological semigroups and corresponding Partial Dierential Equations are equivalent respectively to Hopf-Lax semigroups and the Cauchy problem of a family of rst-order HamiltonJacobi equations. They are related to Maslov idempotent analysis too. The OrnsteinUhlenbeck operator and OrnsteinUhlenbeck semigroup play the role of the Laplacian and the heat kernel semigroup if the Lebesgue measure is replaced by the standard Gaussian measure. In this paper we revisit some contributions on the idempotent analogue of the semigroups associated with the OrnsteinUhlenbeck semigroup, which are based on a Maslov measure, as well as the associated rst-order HamiltonJacobi equation. We study the relevance of the corresponding semigroups in the context of morphological erosions and dilations.

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Section: Introductionmentioning

confidence: 99%

Morphological Counterpart of Ornstein–Uhlenbeck Semigroups and PDEs

Angulo

2022

Lecture Notes in Computer Science

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“…We now briefly review some of these operators formulated as Hamilton-Jacobi equations, curve evolution level sets and morphological flows. For a detailed review and numerical algorithms, see [2,25].…”

Section: Introductionmentioning

confidence: 99%

“…Other particular forms of the Hamilton-Jacobi model Equation (1) cover the flat morphology by disks [7] (i.e., f t = ±||∇ f ||), as well as operators with more general P-power concave structuring functions (i.e., f t = ±||∇ f || p ). For the application of the latter model to adaptive morphology, see [25] and the references therein.…”

Section: Introductionmentioning

confidence: 99%

Morphological PDEs on Graphs for Image Processing on Surfaces and Point Clouds

Elmoataz

Lozes

Talbot

2016

IJGI

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Partial Differential Equations (PDEs)-based morphology offers a wide range of continuous operators to address various image processing problems. Most of these operators are formulated as Hamilton-Jacobi equations or curve evolution level set and morphological flows. In our previous works, we have proposed a simple method to solve PDEs on point clouds using the framework of PdEs (Partial difference Equations) on graphs. In this paper, we propose to apply a large class of morphological-based operators on graphs for processing raw 3D point clouds and extend their applications for the processing of colored point clouds of geo-informatics 3D data. Through illustrations, we show that this simple framework can be used in the resolution of many applications for geo-informatics purposes.

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“…More recently, morphological semigroups for functions on length spaces have been studied [3], whose basic ingredients are the convolution in the (max, +)-algebra (or supremal convolution), the metric distance and a convex shape function. More precisely, given a length space (X, d), a bounded function f : X → R and an increasing convex one-dimensional (shape) function L : R + → R + such that L(0) = 0, the multiscale dilation D L; t f and erosion E L; t f operators of f on (X, d) according to L at scale t > 0 are dened as D L; t f (x) = sup y∈X f (y) − tL d(x, y) t , ∀x ∈ X, E L; t f (x) = inf y∈X f (y) + tL d(x, y) t , ∀x ∈ X.…”

Section: Introductionmentioning

confidence: 99%

Morphological Semigroups and Scale-Spaces on Ultrametric Spaces

Angulo

Velasco-Forero

2017

Lecture Notes in Computer Science

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Abstract. Ultrametric spaces are the natural mathematical structure to deal with data embedded into a hierarchical representation. This kind of representations is ubiquitous in morphological image processing, from pyramids of nested partitions to more abstract dendograms from minimum spanning trees. This paper is a formal study of morphological operators for functions dened on ultrametric spaces. First, the notion of ultrametric structuring function is introduced. Then, using as basic ingredient the convolution in (max,min)-algebra, the multi-scale ultrametric dilation and erosion are dened and their semigroup properties are stated. It is proved in particular that they are idempotent operators and consequently they are algebraically ultrametric closing and opening too. Some preliminary examples illustrate the behavior and practical interest of ultrametric dilations/erosions.

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Morphological PDE and Dilation/Erosion Semigroups on Length Spaces

Cited by 4 publications

References 28 publications

Morphological Counterpart of Ornstein–Uhlenbeck Semigroups and PDEs

Morphological Counterpart of Ornstein–Uhlenbeck Semigroups and PDEs

Morphological PDEs on Graphs for Image Processing on Surfaces and Point Clouds

Morphological Semigroups and Scale-Spaces on Ultrametric Spaces

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