159 lines
4.5 KiB
Python
159 lines
4.5 KiB
Python
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"""Modularity matrix of graphs.
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"""
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import networkx as nx
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from networkx.utils import not_implemented_for
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__all__ = ["modularity_matrix", "directed_modularity_matrix"]
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@not_implemented_for("directed")
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@not_implemented_for("multigraph")
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def modularity_matrix(G, nodelist=None, weight=None):
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r"""Returns the modularity matrix of G.
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The modularity matrix is the matrix B = A - <A>, where A is the adjacency
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matrix and <A> is the average adjacency matrix, assuming that the graph
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is described by the configuration model.
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More specifically, the element B_ij of B is defined as
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.. math::
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A_{ij} - {k_i k_j \over 2 m}
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where k_i is the degree of node i, and where m is the number of edges
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in the graph. When weight is set to a name of an attribute edge, Aij, k_i,
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k_j and m are computed using its value.
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Parameters
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----------
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G : Graph
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A NetworkX graph
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nodelist : list, optional
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The rows and columns are ordered according to the nodes in nodelist.
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If nodelist is None, then the ordering is produced by G.nodes().
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weight : string or None, optional (default=None)
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The edge attribute that holds the numerical value used for
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the edge weight. If None then all edge weights are 1.
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Returns
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-------
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B : Numpy matrix
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The modularity matrix of G.
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Examples
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--------
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>>> k = [3, 2, 2, 1, 0]
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>>> G = nx.havel_hakimi_graph(k)
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>>> B = nx.modularity_matrix(G)
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See Also
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--------
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to_numpy_array
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modularity_spectrum
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adjacency_matrix
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directed_modularity_matrix
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References
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----------
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.. [1] M. E. J. Newman, "Modularity and community structure in networks",
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Proc. Natl. Acad. Sci. USA, vol. 103, pp. 8577-8582, 2006.
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"""
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if nodelist is None:
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nodelist = list(G)
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A = nx.to_scipy_sparse_matrix(G, nodelist=nodelist, weight=weight, format="csr")
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k = A.sum(axis=1)
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m = k.sum() * 0.5
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# Expected adjacency matrix
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X = k * k.transpose() / (2 * m)
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return A - X
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@not_implemented_for("undirected")
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@not_implemented_for("multigraph")
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def directed_modularity_matrix(G, nodelist=None, weight=None):
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"""Returns the directed modularity matrix of G.
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The modularity matrix is the matrix B = A - <A>, where A is the adjacency
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matrix and <A> is the expected adjacency matrix, assuming that the graph
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is described by the configuration model.
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More specifically, the element B_ij of B is defined as
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.. math::
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B_{ij} = A_{ij} - k_i^{out} k_j^{in} / m
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where :math:`k_i^{in}` is the in degree of node i, and :math:`k_j^{out}` is the out degree
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of node j, with m the number of edges in the graph. When weight is set
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to a name of an attribute edge, Aij, k_i, k_j and m are computed using
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its value.
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Parameters
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----------
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G : DiGraph
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A NetworkX DiGraph
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nodelist : list, optional
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The rows and columns are ordered according to the nodes in nodelist.
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If nodelist is None, then the ordering is produced by G.nodes().
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weight : string or None, optional (default=None)
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The edge attribute that holds the numerical value used for
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the edge weight. If None then all edge weights are 1.
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Returns
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-------
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B : Numpy matrix
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The modularity matrix of G.
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Examples
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--------
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>>> G = nx.DiGraph()
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>>> G.add_edges_from(
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... (
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... (1, 2),
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... (1, 3),
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... (3, 1),
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... (3, 2),
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... (3, 5),
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... (4, 5),
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... (4, 6),
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... (5, 4),
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... (5, 6),
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... (6, 4),
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... )
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... )
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>>> B = nx.directed_modularity_matrix(G)
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Notes
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-----
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NetworkX defines the element A_ij of the adjacency matrix as 1 if there
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is a link going from node i to node j. Leicht and Newman use the opposite
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definition. This explains the different expression for B_ij.
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See Also
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--------
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to_numpy_array
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modularity_spectrum
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adjacency_matrix
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modularity_matrix
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References
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----------
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.. [1] E. A. Leicht, M. E. J. Newman,
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"Community structure in directed networks",
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Phys. Rev Lett., vol. 100, no. 11, p. 118703, 2008.
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"""
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if nodelist is None:
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nodelist = list(G)
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A = nx.to_scipy_sparse_matrix(G, nodelist=nodelist, weight=weight, format="csr")
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k_in = A.sum(axis=0)
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k_out = A.sum(axis=1)
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m = k_in.sum()
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# Expected adjacency matrix
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X = k_out * k_in / m
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return A - X
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