:class:`CohomologyPersistence` class
====================================
The :ref:`rips-pairwise-cohomology` illustrates the use of :class:`CohomologyPersistence`.
.. class:: CohomologyPersistence
.. method:: __init__(prime = 11)
Initializes :class:`CohomologyPersistence` with the given `prime`; from
this point on all the computation will be performed with coefficients
in :math:`\mathbb{Z}/prime \mathbb{Z}`.
.. method:: add(boundary, birth, [store = True], [image = True], [coefficients = []])
Adds a simplex with the given `boundary` to the complex, i.e.
:math:`K_{i+1} = K_i \cup \sigma` and `boundary` = :math:`\partial \sigma`.
If a new class is born as a result of the addition, `birth` is stored with
it for future reference.
If `store` is ``False`` and a class is born, it will not be stored in
:class:`CohomologyPersistence`. This avoids wasting space on the
classes of the dimension equal to the maximum-dimensional simplices of
the complex since such classes will never die.
The `image` parameter allows one to work with a case of a space
:math:`L \subseteq K` where the filtration of :math:`K` induces a
filtration of :math:`L`. In this case, one may want to compute **image
persistence** (i.e. the persistence of the sequences of the images given
by the inclusion of :math:`L` in :math:`K`). `image` indicates whether
the simplex added belongs to :math:`L` or not.
If given, `coefficients` is a list parallel to `boundary` that provides
coefficients for the corresponding boundary elements. If empty, it is
assumed to be :math:`(-1)^i`.
:returns: a triple (`i`, `d`, `ccl`). The first element is the index `i`.
It is the internal representation of the newly added simplex,
and should be used later when constructing the
boundaries of its cofaces. In other words, `boundary` must
consist of these indices. The second element `d` is the death
element. It is `None` if a birth occurred, otherwise it
contains the value passed as `birth` to
:meth:`~CohomologyPersistence.add` when the class that just
died was born.
The third element `ccl` returns the dying cocycle
(iterable over instances of :class:`CHSNode`), in case of a death.
It's empty if a birth occurs.
.. method:: __iter__()
Iterator over the live cocycles stored in
:class:`CohomologyPersistence`. The returned elements are of the type
:class:`Cocycle` below.
.. class:: Cocycle
.. attribute:: birth
The birth value associated with the cocycle. It is passed to
:class:`CohomologyPersistence` in method
:meth:`~CohomologyPersistence.add`.
.. method:: __iter__()
Iterator over the individual nodes (simplices) of the cocycle, each of type
:class:`CHSNode`.
.. class:: CHSNode
.. attribute:: si
The index of the simplex, of type :class:`CHSimplexIndex`.
.. attribute:: coefficient
Coefficient in :math:`\mathbb{Z}/prime \mathbb{Z}` associated with the
simplex.
.. class:: CHSimplexIndex
.. attribute:: order
The count associated with the simplex when it is inserted into
:class:`CohomologyPersistence`.
Adaptor
-------
:class:`StaticCohomologyPersistence` provides a wrapper around
class :class:`CohomologyPersistence` that's compatible with :class:`StaticPersistence`.
See the documentation of the latter class for details.
.. class:: StaticCohomologyPersistence
.. method:: __init__(filtration, prime = 2)
Initializes :class:`StaticCohomologyPersistence` with the given
:class:`Filtration`. `prime` is passed straight to the wrapped
:class:`CohomologyPersistence` class.
.. method:: pair_simplices()
Pairs simplices using :class:`CohomologyPersistence` class.
.. method:: __call__(i)
Given a node in the internal representation, the method returns its
integer offset from the beginning of the filtration.
.. method:: make_simplex_map(filtration)
Creates an auxilliary map from the nodes to the simplices::
smap = persistence.make_simplex_map(filtration)
for i in persistence:
if i.unpaired(): print smap[i]
.. method:: __iter__()
Iterator over the nodes (representing individual simplices). See
:class:`APNode`.
.. method:: __len__()
Returns the number of nodes (i.e. the number of simplices).
.. class:: APNode
The following methods behave the same way as they do in :class:`SPNode`.
.. method:: sign()
.. method:: pair()
.. method:: unpaired()
The only crucial distinction in the behavior comes with the attribute
:attr:`cocycle`.
.. attribute:: cocycle
If the simplex is positive, this attribute stores a cocycle it created (recorded at the time of its death).
The 1-dimensional cocycles can be used with the :func:`circular.smooth` function to turn
them into circle-valued maps.
::
for i in persistence:
if i.sign(): print i.cocycle
.. class:: ImagePersistence
This class is another wrapper around :class:`CohomologyPersistence` that can
compute image persistence induced by inclusion of a subcomplex. Its
interface is the same as :class:`StaticCohomologyPersistence` above, except
for the constructor:
.. method:: __init__(filtration, subcomplex)
`subcomplex` is a function called with every simplex. It should return
``True`` if the simplex belong to the subcomplex; ``False`` otherwise.
Circular coordinates
--------------------
.. function:: circular.smooth(filtration, cocycle)
Returns a map from the vertices of the simplicial complex `filtration` to a circle :math:`[-.5, .5]`,
where the opposite ends of the interval are identified.