Difference between revisions of "Publications/boutry.20.jmiv.1"
From LRDE
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| journal = Journal of Mathematical Imaging and Vision |
| journal = Journal of Mathematical Imaging and Vision |
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| volume = 62 |
| volume = 62 |
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| − | | number = |
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| pages = 1256 to 1284 |
| pages = 1256 to 1284 |
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| lrdeprojects = Olena |
| lrdeprojects = Olena |
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| − | | abstract = In discrete topology, we like digitally well-composed (shortly DWC) interpolations because they remove pinches in cubical images. Usual well-composed interpolations are local and sometimes self-dual (they treat in a same way dark and bright components in the image). In our case, we are particularly interested in <math>n</math>-D self-dual DWC interpolations to obtain a purely self-dual tree of shapes. However, it has been proved that we cannot have an <math>n</math>-D interpolation which is at the same time |
+ | | abstract = In discrete topology, we like digitally well-composed (shortly DWC) interpolations because they remove pinches in cubical images. Usual well-composed interpolations are local and sometimes self-dual (they treat in a same way dark and bright components in the image). In our case, we are particularly interested in <math>n</math>-D self-dual DWC interpolations to obtain a purely self-dual tree of shapes. However, it has been proved that we cannot have an <math>n</math>-D interpolation which is at the same time local, self-dualand well-composed. By removing the locality constraint, we have obtained an <math>n</math>-D interpolation with many properties in practice: it is self-dual, DWC, and in-between (this last property means that it preserves the contours). Since we did not published the proofs of these results before, we propose to provide in a first time the proofs of the two last properties here (DWCness and in-betweeness) and a sketch of the proof of self-duality (the complete proof of self-duality requires more material and will come later). Some theoretical and practical results are given. |
| lrdepaper = http://www.lrde.epita.fr/dload/papers/boutry.20.jmiv.1.pdf |
| lrdepaper = http://www.lrde.epita.fr/dload/papers/boutry.20.jmiv.1.pdf |
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| lrdekeywords = Image |
| lrdekeywords = Image |
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journal = <nowiki>{</nowiki>Journal of Mathematical Imaging and Vision<nowiki>}</nowiki>, |
journal = <nowiki>{</nowiki>Journal of Mathematical Imaging and Vision<nowiki>}</nowiki>, |
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volume = <nowiki>{</nowiki>62<nowiki>}</nowiki>, |
volume = <nowiki>{</nowiki>62<nowiki>}</nowiki>, |
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| − | number = <nowiki>{</nowiki><nowiki>}</nowiki>, |
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pages = <nowiki>{</nowiki>1256--1284<nowiki>}</nowiki>, |
pages = <nowiki>{</nowiki>1256--1284<nowiki>}</nowiki>, |
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month = sep, |
month = sep, |
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Revision as of 18:20, 9 November 2020
- Authors
- Nicolas Boutry, Laurent Najman, Thierry Géraud
- Journal
- Journal of Mathematical Imaging and Vision
- Type
- article
- Projects
- Olena
- Keywords
- Image
- Date
- 2020-09-03
Abstract
In discrete topology, we like digitally well-composed (shortly DWC) interpolations because they remove pinches in cubical images. Usual well-composed interpolations are local and sometimes self-dual (they treat in a same way dark and bright components in the image). In our case, we are particularly interested in -D self-dual DWC interpolations to obtain a purely self-dual tree of shapes. However, it has been proved that we cannot have an -D interpolation which is at the same time local, self-dualand well-composed. By removing the locality constraint, we have obtained an -D interpolation with many properties in practice: it is self-dual, DWC, and in-between (this last property means that it preserves the contours). Since we did not published the proofs of these results before, we propose to provide in a first time the proofs of the two last properties here (DWCness and in-betweeness) and a sketch of the proof of self-duality (the complete proof of self-duality requires more material and will come later). Some theoretical and practical results are given.
Documents
Bibtex (lrde.bib)
@Article{ boutry.20.jmiv.1,
author = {Nicolas Boutry and Laurent Najman and Thierry G\'eraud},
title = {Topological Properties of the First Non-Local Digitally
Well-Composed Interpolation on {$n$-D} Cubical Grids},
journal = {Journal of Mathematical Imaging and Vision},
volume = {62},
pages = {1256--1284},
month = sep,
year = {2020},
abstract = {In discrete topology, we like digitally well-composed
(shortly DWC) interpolations because they remove pinches in
cubical images. Usual well-composed interpolations are
local and sometimes self-dual (they treat in a same way
dark and bright components in the image). In our case, we
are particularly interested in $n$-D self-dual DWC
interpolations to obtain a purely self-dual tree of shapes.
However, it has been proved that we cannot have an $n$-D
interpolation which is at the same time local, self-dual,
and well-composed. By removing the locality constraint, we
have obtained an $n$-D interpolation with many properties
in practice: it is self-dual, DWC, and in-between (this
last property means that it preserves the contours). Since
we did not published the proofs of these results before, we
propose to provide in a first time the proofs of the two
last properties here (DWCness and in-betweeness) and a
sketch of the proof of self-duality (the complete proof of
self-duality requires more material and will come later).
Some theoretical and practical results are given. }
}