Difference between revisions of "JavaPlex Tutorial"
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JavaPlex implements [[abstract simplicial complex|abstract simplicial complexes]] via ''simplex streams'', which are provided by the function | JavaPlex implements [[abstract simplicial complex|abstract simplicial complexes]] via ''simplex streams'', which are provided by the function | ||
api.Plex4.createExplicitSimplexStream() | api.Plex4.createExplicitSimplexStream() | ||
| − | To | + | To a simplex stream we assign vertices and higher simplices as exemplified below. |
'''Example: 1-sphere''' | '''Example: 1-sphere''' | ||
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'''Example: 1-sphere''' | '''Example: 1-sphere''' | ||
| + | |||
Continuing our example from above, the homology groups over <math> \mathbb{Z}/2\mathbb{Z}</math> of <code>complex</code> up to dimension 3 can be extracted via | Continuing our example from above, the homology groups over <math> \mathbb{Z}/2\mathbb{Z}</math> of <code>complex</code> up to dimension 3 can be extracted via | ||
homology = api.Plex4.getModularSimplicialAlgorithm(3, 2); | homology = api.Plex4.getModularSimplicialAlgorithm(3, 2); | ||
Revision as of 16:11, 5 May 2019
In this tutorial we will learn how to use the JavaPlex[1] package in Matlab. For a more complete picture of JavaPlex please visit the projects homepage and consider also reading the tutorial provided there.
Installation
To use JavaPlex with Matlab you will need a working version of Matlab.
Furthermore, JavaPlex requires Java version number 1.5 or higher.
You can check your Java version in Matlab by entering version -java
To install JavaPlex in Matlab go to the latest release at [1]. Download the zip file of matlab examples, named something like matlab-examples-4.3.4.zip.
Unzip the folder to a known location, by default the resulting folder is called matlab_examples.
In Matlab, change your current folder to matlab_examples. Run the script load_javaplex.m that resides in this folder and import the JavaPlex routines provided by the package.
You can do this by entering the following commands into the command line
load_javaplex.m; import edu.stanford.math.plex4.*;
You will need to reload the package with these commands every time you open a new Matlab session.
To check wether JavaPlex was loaded correctly, e.g. enter api.Plex4.createExplicitSimplexStream()
which will return something like
ans = edu.stanford.math.plex4.streams.impl.ExplicitSimplexStream@513fd4
Basic constructions
Simplex Streams
JavaPlex implements abstract simplicial complexes via simplex streams, which are provided by the function
api.Plex4.createExplicitSimplexStream()
To a simplex stream we assign vertices and higher simplices as exemplified below.
Example: 1-sphere
In order to build a simplicial complex by hand, we first load the relevant function onto our target object
complex = api.Plex4.createExplicitSimplexStream();
and pass the vertices of the complex to it:
complex.addVertex(0); complex.addVertex(1); complex.addVertex(2);
In general a complex will have higher simplicies, which by definition are sets of vertices. These are added to the simplicial complex by similarly passing sets to the stream.
complex.addElement([0, 1]); complex.addElement([0, 2]); complex.addElement([1, 2]);
Once all simplices have been put into the stream, we close it by calling
complex.finalizeStream();
At this point complex is a simplicial complex that encodes the boundary of a triangle.
We can get the number of simplices (of all dimension) contained in the simplicial complex by calling
complex.getSize()
Modular Simplicial Algorithm
For a given simplicial complex [math]X[/math], the function
api.Plex4.getModularSimplicialAlgorithm(d, p)
provides an algorithm that can calculate the persistence module of homology groups [math]H_i(X,\mathbb{Z}/p\mathbb{Z})[/math] for all [math] i\leq d[/math], together with representatives of the classes [math] [x]\in H_i [/math].
Note: This algorithm is used more generally for filtered complexes as discussed below. Every simplicial complex [math]X[/math] is trivially filtered by [math] \mathcal{F}_t(X) = X [/math] for all [math]t \in \mathbb{R}[/math].
Example: 1-sphere
Continuing our example from above, the homology groups over [math] \mathbb{Z}/2\mathbb{Z}[/math] of complex up to dimension 3 can be extracted via
homology = api.Plex4.getModularSimplicialAlgorithm(3, 2); persistenceIntervals = homology.computeIntervals(complex)
The output is a number of intervals, that tell us for which values of the filtration parameter a non-trivial homology class exists. If we are also interested in representatives of the non-trivial classes we can use
persistenceAnnotatedIntervals = homology.computeAnnotatedIntervals(complex)
This gives the parameter values of non-trivial classes together with their representatives.
Example: [math]n[/math]-Sphere
The explicit construction above is of course too tiresome for more complicated simplicial complexes. We exemplify which additional methods of simplex stream objects exist, by constructing [math] n[/math]-spheres.
% set dimension and load simplex stream dimension = 9; sphere = api.Plex4.createExplicitSimplexStream(); % construct simplicial sphere stream.addElement(0:(dimension + 1)); stream.ensureAllFaces(); stream.removeElementIfPresent(0:(dimension + 1)); stream.finalizeStream(); % print out the total number of simplices in the complex stream.getSize() % get homology algorithm over Z/2Z up to dimension+1 persistence = api.Plex4.getModularSimplicialAlgorithm(dimension + 1, 2); % compute and print the homology groups intervals = persistence.computeIntervals(stream)
Filtered Chain Complexes
Generating Barcodes
Customization
Examples
We can now use what we've learned above to investigate more complicated data sets.