Source code for networkx.linalg.spectrum
"""
Eigenvalue spectrum of graphs.
"""
import networkx as nx
__all__ = [
"laplacian_spectrum",
"adjacency_spectrum",
"modularity_spectrum",
"normalized_laplacian_spectrum",
"bethe_hessian_spectrum",
]
[docs]def laplacian_spectrum(G, weight="weight"):
"""Returns eigenvalues of the Laplacian of G
Parameters
----------
G : graph
A NetworkX graph
weight : string or None, optional (default='weight')
The edge data key used to compute each value in the matrix.
If None, then each edge has weight 1.
Returns
-------
evals : NumPy array
Eigenvalues
Notes
-----
For MultiGraph/MultiDiGraph, the edges weights are summed.
See to_numpy_array for other options.
See Also
--------
laplacian_matrix
"""
import scipy as sp
import scipy.linalg # call as sp.linalg
return sp.linalg.eigvalsh(nx.laplacian_matrix(G, weight=weight).todense())
[docs]def normalized_laplacian_spectrum(G, weight="weight"):
"""Return eigenvalues of the normalized Laplacian of G
Parameters
----------
G : graph
A NetworkX graph
weight : string or None, optional (default='weight')
The edge data key used to compute each value in the matrix.
If None, then each edge has weight 1.
Returns
-------
evals : NumPy array
Eigenvalues
Notes
-----
For MultiGraph/MultiDiGraph, the edges weights are summed.
See to_numpy_array for other options.
See Also
--------
normalized_laplacian_matrix
"""
import scipy as sp
import scipy.linalg # call as sp.linalg
return sp.linalg.eigvalsh(
nx.normalized_laplacian_matrix(G, weight=weight).todense()
)
[docs]def adjacency_spectrum(G, weight="weight"):
"""Returns eigenvalues of the adjacency matrix of G.
Parameters
----------
G : graph
A NetworkX graph
weight : string or None, optional (default='weight')
The edge data key used to compute each value in the matrix.
If None, then each edge has weight 1.
Returns
-------
evals : NumPy array
Eigenvalues
Notes
-----
For MultiGraph/MultiDiGraph, the edges weights are summed.
See to_numpy_array for other options.
See Also
--------
adjacency_matrix
"""
import scipy as sp
import scipy.linalg # call as sp.linalg
return sp.linalg.eigvals(nx.adjacency_matrix(G, weight=weight).todense())
[docs]def modularity_spectrum(G):
"""Returns eigenvalues of the modularity matrix of G.
Parameters
----------
G : Graph
A NetworkX Graph or DiGraph
Returns
-------
evals : NumPy array
Eigenvalues
See Also
--------
modularity_matrix
References
----------
.. [1] M. E. J. Newman, "Modularity and community structure in networks",
Proc. Natl. Acad. Sci. USA, vol. 103, pp. 8577-8582, 2006.
"""
import scipy as sp
import scipy.linalg # call as sp.linalg
if G.is_directed():
return sp.linalg.eigvals(nx.directed_modularity_matrix(G))
else:
return sp.linalg.eigvals(nx.modularity_matrix(G))
[docs]def bethe_hessian_spectrum(G, r=None):
"""Returns eigenvalues of the Bethe Hessian matrix of G.
Parameters
----------
G : Graph
A NetworkX Graph or DiGraph
r : float
Regularizer parameter
Returns
-------
evals : NumPy array
Eigenvalues
See Also
--------
bethe_hessian_matrix
References
----------
.. [1] A. Saade, F. Krzakala and L. Zdeborová
"Spectral clustering of graphs with the bethe hessian",
Advances in Neural Information Processing Systems. 2014.
"""
import scipy as sp
import scipy.linalg # call as sp.linalg
return sp.linalg.eigvalsh(nx.bethe_hessian_matrix(G, r).todense())