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author | Gard Spreemann <gspr@nonempty.org> | 2019-09-25 14:29:41 +0200 |
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committer | Gard Spreemann <gspr@nonempty.org> | 2019-09-25 14:29:41 +0200 |
commit | 599d68cd916f533bdb66dd9e684dd5703233b6bb (patch) | |
tree | 4b825dc642cb6eb9a060e54bf8d69288fbee4904 /doc/Persistent_cohomology/Intro_persistent_cohomology.h | |
parent | a2e642954ae39025e041471d486ecbac25dff440 (diff) |
Delete all files in order to incorporate upstream's move to git.
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diff --git a/doc/Persistent_cohomology/Intro_persistent_cohomology.h b/doc/Persistent_cohomology/Intro_persistent_cohomology.h deleted file mode 100644 index 5fb9d4d2..00000000 --- a/doc/Persistent_cohomology/Intro_persistent_cohomology.h +++ /dev/null @@ -1,270 +0,0 @@ -/* This file is part of the Gudhi Library. The Gudhi library - * (Geometric Understanding in Higher Dimensions) is a generic C++ - * library for computational topology. - * - * Author(s): Clément Maria - * - * Copyright (C) 2014 Inria - * - * This program is free software: you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation, either version 3 of the License, or - * (at your option) any later version. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program. If not, see <http://www.gnu.org/licenses/>. - */ - -#ifndef DOC_PERSISTENT_COHOMOLOGY_INTRO_PERSISTENT_COHOMOLOGY_H_ -#define DOC_PERSISTENT_COHOMOLOGY_INTRO_PERSISTENT_COHOMOLOGY_H_ - -// needs namespace for Doxygen to link on classes -namespace Gudhi { -// needs namespace for Doxygen to link on classes -namespace persistent_cohomology { - -/** \defgroup persistent_cohomology Persistent Cohomology - - \author Clément Maria - - Computation of persistent cohomology using the algorithm of - \cite DBLP:journals/dcg/SilvaMV11 and \cite DBLP:journals/corr/abs-1208-5018 - and the Compressed Annotation Matrix - implementation of \cite DBLP:conf/esa/BoissonnatDM13 - - The theory of homology consists in attaching to a topological space a sequence of - (homology) groups, - capturing global topological features - like connected components, holes, cavities, etc. Persistent homology studies the evolution - -- birth, life and death -- of - these features when the topological space is changing. Consequently, the theory is essentially - composed of three elements: - topological spaces, their homology groups and an evolution scheme. - - \section persistencetopolocalspaces Topological Spaces - Topological spaces are represented by simplicial complexes. - Let \f$V = \{1, \cdots ,|V|\}\f$ be a set of <EM>vertices</EM>. - A <EM>simplex</EM> \f$\sigma\f$ is a subset of vertices - \f$\sigma \subseteq V\f$. A <EM>simplicial complex</EM> \f$\mathbf{K}\f$ - on \f$V\f$ is a collection of simplices \f$\{\sigma\}\f$, - \f$\sigma \subseteq V\f$, such that \f$\tau \subseteq \sigma \in \mathbf{K} - \Rightarrow \tau \in \mathbf{K}\f$. The dimension \f$n=|\sigma|-1\f$ of \f$\sigma\f$ - is its number of elements minus 1. A <EM>filtration</EM> of a simplicial complex is - a function \f$f:\mathbf{K} \rightarrow \mathbb{R}\f$ satisfying \f$f(\tau)\leq - f(\sigma)\f$ whenever \f$\tau \subseteq \sigma\f$. - - We define the concept FilteredComplex which enumerates the requirements for a class - to represent a filtered complex from which persistent homology may be computed. - We use the vocabulary of simplicial complexes, but the concept - is valid for any type of cell complex. The main requirements - are the definition of: - \li type <CODE>Indexing_tag</CODE>, which is a model of the concept - <CODE>IndexingTag</CODE>, - describing the nature of the indexing scheme, - \li type Simplex_handle to manipulate simplices, - \li method <CODE>int dimension(Simplex_handle)</CODE> returning - the dimension of a simplex, - \li type and method <CODE>Boundary_simplex_range - boundary_simplex_range(Simplex_handle)</CODE> that returns - a range giving access to the codimension 1 subsimplices of the - input simplex, as-well-as the coefficients \f$(-1)^i\f$ in the - definition of the operator \f$\partial\f$. The iterators have - value type <CODE>Simplex_handle</CODE>, - \li type and method - <CODE>Filtration_simplex_range filtration_simplex_range ()</CODE> - that returns a range giving - access to all the simplices of the complex read in the order - assigned by the indexing scheme, - \li type and method - <CODE>Filtration_value filtration (Simplex_handle)</CODE> that returns the value of - the filtration on the simplex represented by the handle. - - \section persistencehomology Homology - For a ring \f$\mathcal{R}\f$, the group of <EM>n-chains</EM>, - denoted \f$\mathbf{C}_n(\mathbf{K},\mathcal{R})\f$, of \f$\mathbf{K}\f$ is the - group of formal sums of - n-simplices with \f$\mathcal{R}\f$ coefficients. The <EM>boundary operator</EM> is a - linear operator - \f$\partial_n: \mathbf{C}_n(\mathbf{K},\mathcal{R}) \rightarrow \mathbf{C}_{n-1}(\mathbf{K},\mathcal{R})\f$ - such that \f$\partial_n \sigma = \partial_n [v_0, \cdots , v_n] = - \sum_{i=0}^n (-1)^{i}[v_0,\cdots ,\widehat{v_i}, \cdots,v_n]\f$, - where \f$\widehat{v_i}\f$ means \f$v_i\f$ is omitted from the list. The chain - groups form a sequence: - - \f[\cdots \ \ \mathbf{C}_n(\mathbf{K},\mathcal{R}) \xrightarrow{\ \partial_n\ } \mathbf{C}_{n-1}(\mathbf{K},\mathcal{R}) - \xrightarrow{\partial_{n-1}} \cdots \xrightarrow{\ \partial_2 \ } - \mathbf{C}_1(\mathbf{K},\mathcal{R}) \xrightarrow{\ \partial_1 \ } \mathbf{C}_0(\mathbf{K},\mathcal{R}) \f] - - of finitely many groups \f$\mathbf{C}_n(\mathbf{K},\mathcal{R})\f$ and homomorphisms - \f$\partial_n\f$, indexed by the dimension \f$n \geq 0\f$. - The boundary operators satisfy the property \f$\partial_n \circ \partial_{n+1}=0\f$ - for every \f$n > 0\f$ - and we define the homology groups: - - \f[\mathbf{H}_n(\mathbf{K},\mathcal{R}) = \ker \partial_n / \mathrm{im} \ \partial_{n+1}\f] - - We refer to \cite Munkres-elementsalgtop1984 for an introduction to homology - theory and to \cite DBLP:books/daglib/0025666 for an introduction to persistent homology. - - \section persistenceindexingscheme Indexing Scheme - "Changing" a simplicial complex consists in applying a simplicial map. - An <EM>indexing scheme</EM> is a directed graph together with a traversal - order, such that two - consecutive nodes in the graph are connected by an arrow (either forward or backward). - The nodes represent simplicial complexes and the directed edges simplicial maps. - - From the computational point of view, there are two types of indexing schemes of - interest - in persistent homology: <EM>linear</EM> ones - \f$\bullet \longrightarrow \bullet \longrightarrow \cdots \longrightarrow \bullet - \longrightarrow \bullet\f$ - in persistent homology \cite DBLP:journals/dcg/ZomorodianC05 , - and <EM>zigzag</EM> ones - \f$\bullet \longrightarrow \bullet \longleftarrow \cdots - \longrightarrow \bullet - \longleftarrow \bullet \f$ in zigzag persistent - homology \cite DBLP:journals/focm/CarlssonS10. - These indexing schemes have a natural left-to-right traversal order, and we - describe them with ranges and iterators. - In the current release of the Gudhi library, only the linear case is implemented. - - In the following, we consider the case where the indexing scheme is induced - by a filtration. - Ordering the simplices - by increasing filtration values (breaking ties so as a simplex appears after - its subsimplices of same filtration value) provides an indexing scheme. - -\section pcohexamples Examples - -We provide several example files: run these examples with -h for details on their use, and read the README file. - -\li <a href="_rips_complex_2rips_persistence_8cpp-example.html"> -Rips_complex/rips_persistence.cpp</a> computes the Rips complex of a point cloud and outputs its persistence -diagram. -\code $> ./rips_persistence ../../data/points/tore3D_1307.off -r 0.25 -m 0.5 -d 3 -p 3 \endcode -\code The complex contains 177838 simplices - and has dimension 3 -3 0 0 inf -3 1 0.0983494 inf -3 1 0.104347 inf -3 2 0.138335 inf \endcode - -\li <a href="_persistent_cohomology_2rips_multifield_persistence_8cpp-example.html"> -Persistent_cohomology/rips_multifield_persistence.cpp</a> computes the Rips complex of a point cloud and outputs its -persistence diagram with a family of field coefficients. - -\li <a href="_rips_complex_2rips_distance_matrix_persistence_8cpp-example.html"> -Rips_complex/rips_distance_matrix_persistence.cpp</a> computes the Rips complex of a distance matrix and -outputs its persistence diagram. - -The file should contain square or lower triangular distance matrix with semicolons as separators. -The code do not check if it is dealing with a distance matrix. It is the user responsibility to provide a valid input. -Please refer to data/distance_matrix/lower_triangular_distance_matrix.csv for an example of a file. - -\li <a href="_rips_complex_2rips_correlation_matrix_persistence_8cpp-example.html"> -Rips_complex/rips_correlation_matrix_persistence.cpp</a> -computes the Rips complex of a correlation matrix and outputs its persistence diagram. - -Note that no check is performed if the matrix given as the input is a correlation matrix. -It is the user responsibility to ensure that this is the case. The input is to be given either as a square or a lower -triangular matrix. -Please refer to data/correlation_matrix/lower_triangular_correlation_matrix.csv for an example of a file. - -\li <a href="_alpha_complex_2alpha_complex_3d_persistence_8cpp-example.html"> -Alpha_complex/alpha_complex_3d_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/2\mathbb{Z}\f$ coefficients of the alpha complex on points sampling from an OFF file. -\code $> ./alpha_complex_3d_persistence ../../data/points/tore3D_300.off -p 2 -m 0.45 \endcode -\code Simplex_tree dim: 3 -2 0 0 inf -2 1 0.0682162 1.0001 -2 1 0.0934117 1.00003 -2 2 0.56444 1.03938 \endcode - -\li <a href="_alpha_complex_2exact_alpha_complex_3d_persistence_8cpp-example.html"> -Alpha_complex/exact_alpha_complex_3d_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/2\mathbb{Z}\f$ coefficients of the alpha complex on points sampling from an OFF file. -Here, as CGAL computes the exact values, it is slower, but it is necessary when points are on a grid -for instance. -\code $> ./exact_alpha_complex_3d_persistence ../../data/points/sphere3D_pts_on_grid.off -p 2 -m 0.1 \endcode -\code Simplex_tree dim: 3 -2 0 0 inf -2 2 0.0002 0.2028 \endcode - -\li <a href="_alpha_complex_2weighted_alpha_complex_3d_persistence_8cpp-example.html"> -Alpha_complex/weighted_alpha_complex_3d_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/2\mathbb{Z}\f$ coefficients of the weighted alpha complex on points sampling from an OFF file -and a weights file. -\code $> ./weighted_alpha_complex_3d_persistence ../../data/points/tore3D_300.off -../../data/points/tore3D_300.weights -p 2 -m 0.45 \endcode -\code Simplex_tree dim: 3 -2 0 -1 inf -2 1 -0.931784 0.000103311 -2 1 -0.906588 2.60165e-05 -2 2 -0.43556 0.0393798 \endcode - -\li <a href="_alpha_complex_2alpha_complex_persistence_8cpp-example.html"> -Alpha_complex/alpha_complex_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/p\mathbb{Z}\f$ coefficients of the alpha complex on points sampling from an OFF file. -\code $> ./alpha_complex_persistence -r 32 -p 2 -m 0.45 ../../data/points/tore3D_300.off \endcode -\code Alpha complex is of dimension 3 - 9273 simplices - 300 vertices. -Simplex_tree dim: 3 -2 0 0 inf -2 1 0.0682162 1.0001 -2 1 0.0934117 1.00003 -2 2 0.56444 1.03938 \endcode - -\li <a href="_alpha_complex_2periodic_alpha_complex_3d_persistence_8cpp-example.html"> -Alpha_complex/periodic_alpha_complex_3d_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/2\mathbb{Z}\f$ coefficients of the periodic alpha complex on points sampling from an OFF file. -The second parameter is a \ref FileFormatsIsoCuboid file with coordinates of the periodic cuboid. -Note that the lengths of the sides of the periodic cuboid have to be the same. -\code $> ./periodic_alpha_complex_3d_persistence ../../data/points/grid_10_10_10_in_0_1.off -../../data/points/iso_cuboid_3_in_0_1.txt -p 3 -m 1.0 \endcode -\code Periodic Delaunay computed. -Simplex_tree dim: 3 -3 0 0 inf -3 1 0.0025 inf -3 1 0.0025 inf -3 1 0.0025 inf -3 2 0.005 inf -3 2 0.005 inf -3 2 0.005 inf -3 3 0.0075 inf \endcode - -\li <a href="_persistent_cohomology_2weighted_periodic_alpha_complex_3d_persistence_8cpp-example.html"> -Persistent_cohomology/weighted_periodic_alpha_complex_3d_persistence.cpp</a> computes the persistent homology with -\f$\mathbb{Z}/2\mathbb{Z}\f$ coefficients of the periodic alpha complex on weighted points from an OFF file. The -additional parameters of this program are:<br> -(a) The file with the weights of points. The file consist of a sequence of numbers (as many as points). -Note that the weight of each single point have to be bounded by 1/64 times the square of the cuboid edge length.<br> -(b) A \ref FileFormatsIsoCuboid file with coordinates of the periodic cuboid. -Note that the lengths of the sides of the periodic cuboid have to be the same.<br> -\code $> ./weighted_periodic_alpha_complex_3d_persistence ../../data/points/shifted_sphere.off -../../data/points/shifted_sphere.weights ../../data/points/iso_cuboid_3_in_0_10.txt 3 1.0 \endcode -\code Weighted Periodic Delaunay computed. -Simplex_tree dim: 3 -3 0 -0.0001 inf -3 1 16.0264 inf -3 1 16.0273 inf -3 1 16.0303 inf -3 2 36.8635 inf -3 2 36.8704 inf -3 2 36.8838 inf -3 3 58.6783 inf \endcode - -\li <a href="_persistent_cohomology_2plain_homology_8cpp-example.html"> -Persistent_cohomology/plain_homology.cpp</a> computes the plain homology of a simple simplicial complex without -filtration values. - - */ - -} // namespace persistent_cohomology - -} // namespace Gudhi - -#endif // DOC_PERSISTENT_COHOMOLOGY_INTRO_PERSISTENT_COHOMOLOGY_H_ |