Spectral decomposition of Laplacian matrices of graphs.
embed_laplacian_matrix(
graph,
no,
weights = NULL,
which = c("lm", "la", "sa"),
type = c("default", "D-A", "DAD", "I-DAD", "OAP"),
scaled = TRUE,
options = igraph.arpack.default
)
A list containing with entries:
Estimated latent positions,
an n
times no
matrix, n
is the number of vertices.
NULL
for undirected graphs, the second half of the latent
positions for directed graphs, an n
times no
matrix, n
is the number of vertices.
The eigenvalues (for undirected graphs) or the singular values (for directed graphs) calculated by the algorithm.
A named list, information about the underlying ARPACK
computation. See arpack
for the details.
The input graph, directed or undirected.
An integer scalar. This value is the embedding dimension of the
spectral embedding. Should be smaller than the number of vertices. The
largest no
-dimensional non-zero singular values are used for the
spectral embedding.
Optional positive weight vector for calculating a weighted
embedding. If the graph has a weight
edge attribute, then this is
used by default. For weighted embedding, edge weights are used instead
of the binary adjacency matrix, and vertex strength (see
strength
) is used instead of the degrees.
Which eigenvalues (or singular values, for directed graphs) to use. ‘lm’ means the ones with the largest magnitude, ‘la’ is the ones (algebraic) largest, and ‘sa’ is the (algebraic) smallest eigenvalues. The default is ‘lm’. Note that for directed graphs ‘la’ and ‘lm’ are the equivalent, because the singular values are used for the ordering.
The type of the Laplacian to use. Various definitions exist for the Laplacian of a graph, and one can choose between them with this argument.
Possible values: D-A
means \(D-A\) where \(D\) is the degree
matrix and \(A\) is the adjacency matrix; DAD
means
\(D^{1/2}\) times \(A\) times \(D^{1/2}{D^1/2}\),
\(D^{1/2}\) is the inverse of the square root of the degree matrix;
I-DAD
means \(I-D^{1/2}\), where \(I\) is the identity
matrix. OAP
is \(O^{1/2}AP^{1/2}\), where
\(O^{1/2}\) is the inverse of the square root of the out-degree
matrix and \(P^{1/2}\) is the same for the in-degree matrix.
OAP
is not defined for undirected graphs, and is the only defined type
for directed graphs.
The default (i.e. type default
) is to use D-A
for undirected
graphs and OAP
for directed graphs.
Logical scalar, if FALSE
, then \(U\) and \(V\) are
returned instead of \(X\) and \(Y\).
A named list containing the parameters for the SVD
computation algorithm in ARPACK. By default, the list of values is assigned
the values given by igraph.arpack.default
.
Gabor Csardi csardi.gabor@gmail.com
This function computes a no
-dimensional Euclidean representation of
the graph based on its Laplacian matrix, \(L\). This representation is
computed via the singular value decomposition of the Laplacian matrix.
They are essentially doing the same as embed_adjacency_matrix
,
but work on the Laplacian matrix, instead of the adjacency matrix.
Sussman, D.L., Tang, M., Fishkind, D.E., Priebe, C.E. A Consistent Adjacency Spectral Embedding for Stochastic Blockmodel Graphs, Journal of the American Statistical Association, Vol. 107(499), 2012
embed_adjacency_matrix
,
sample_dot_product
## A small graph
lpvs <- matrix(rnorm(200), 20, 10)
lpvs <- apply(lpvs, 2, function(x) { return (abs(x)/sqrt(sum(x^2))) })
RDP <- sample_dot_product(lpvs)
embed <- embed_laplacian_matrix(RDP, 5)
Run the code above in your browser using DataLab