Difference between revisions of "Publications/geraud.13.ismm"
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Revision as of 10:00, 25 November 2014
- Authors
- Thierry Géraud, Edwin Carlinet, Sébastien Crozet, Laurent Najman
- Where
- Mathematical Morphology and Its Application to Signal and Image Processing -- Proceedings of the 11th International Symposium on Mathematical Morphology (ISMM)
- Place
- Uppsala, Sweden
- Type
- inproceedings
- Publisher
- Springer
- Keywords
- Image
- Date
- 2013-03-14
Abstract
To compute the morphological self-dual representation of images, namely the tree of shapes, the state-of-the-art algorithms do not have a satisfactory time complexity. Furthermore the proposed algorithms are only effective for 2D images and they are far from being simple to implement. That is really penalizing since a self-dual represen- tation of images is a structure that gives rise to many powerful operators and applications, and that could be very useful for 3D images. In this paper we propose a simple-to-write algorithm to compute the tree of shapes; it works for nD images and has a quasi-linear complexity when data quantization is low, typically 12 bits or less. To get that result, this paper introduces a novel representation of images that has some amazing properties of continuitywhile remaining discrete.
Documents
Bibtex (lrde.bib)
@InProceedings{ geraud.13.ismm,
author = {Thierry G\'eraud and Edwin Carlinet and S\'ebastien Crozet
and Laurent Najman},
title = {A quasi-linear algorithm to compute the tree of shapes of
{$n$-D} images.},
booktitle = {Mathematical Morphology and Its Application to Signal and
Image Processing -- Proceedings of the 11th International
Symposium on Mathematical Morphology (ISMM)},
year = 2013,
editor = {C.L. Luengo Hendriks and G. Borgefors and R. Strand},
volume = 7883,
series = {Lecture Notes in Computer Science Series},
address = {Uppsala, Sweden},
publisher = {Springer},
pages = {98--110},
project = {Image},
abstract = {To compute the morphological self-dual representation of
images, namely the tree of shapes, the state-of-the-art
algorithms do not have a satisfactory time complexity.
Furthermore the proposed algorithms are only effective for
2D images and they are far from being simple to implement.
That is really penalizing since a self-dual represen-
tation of images is a structure that gives rise to many
powerful operators and applications, and that could be very
useful for 3D images. In this paper we propose a
simple-to-write algorithm to compute the tree of shapes; it
works for nD images and has a quasi-linear complexity when
data quantization is low, typically 12 bits or less. To get
that result, this paper introduces a novel representation
of images that has some amazing properties of continuity,
while remaining discrete.}
}