jordan: Utilities for Jordan matrices
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jordan R Documentation
Utilities for Jordan matrices
Description
Utility functions for work with the Jordan decompositions of matrices:
create a block diagonal matrix of Jordan blocks,
restore a matrix from its Jordan decomposition,
locate specific chains.
Usage
Jordan_matrix(eigval, len.block)
from_Jordan(x, jmat, ...)
chain_ind(chainno, len.block)
chains_to_list(vectors, heights)
Arguments
eigval
eigenvalues, a numeric or complex vector.
len.block
lengths of Jordan chains, a vector of positive integers.
x
generalised eigenvectors, a matrix with one column for each
(generalised) eigenvector.
jmat
a Jordan matrix.
chainno
a vector of positive integers between 1 and length(eigval)
specifying which Jordan chains to locate, see Details.
...
further arguments to pass on to solve.
vectors
a matrix of generalised eigenvectors of a matrix.
heights
a vector of chain lengths, heights[i] is the length of the
i-th chain.
Details
Jordan_matrix creates a Jordan matrix (block-diagonal matrix
with Jordan blocks on the diagonal) whose i-th diagonal block
corresponds to eigval[i] and is of size len.block[i].
If len.block is missing, Jordan_matrix returns
diag(eigenvalues).
from_Jordan computes the matrix whose Jordan decomposition is
represented by arguments X (chains) and J (Jordan
matrix). Conceptually, the result is equivalent to XJX^{-1} but
without explicitly inverting matrices (currently the result is the
transpose of solve(t(x), t(x %*% jmat), ...)).
chain_ind computes the columns of specified Jordan chains in a
matrix of generalised eigenvectors. It is mostly internal function.
If x is a matrix whose columns are generalised eigenvectors and
the i-th Jordan chain is of length len.block[i], then this
function gives the column numbers of x containing the specified
chains.
Note that chain_ind is not able to deduce the total number of
eigenvalues. It is therefore an error to omit argument
len.block when calling it.
chains_to_list converts the matrix vectors into a list
of matrices. The i-th element of this list is a matrix whose columns
are the vectors in the i-th chain.
Value
for Jordan_matrix, a matrix with the specified Jordan blocks on
its diagonal.
for from_Jordan, the matrix with the specified Jordan
decomposition.
for chain_ind, a vector of positive integers giving the columns
of the requested chains.
for chains_to_list, a list of matrices.
Level
0
Author(s)
Georgi N. Boshnakov
Examples
## single Jordan blocks
Jordan_matrix(4, 2)
Jordan_matrix(5, 3)
Jordan_matrix(6, 1)
## a matrix with the above 3 blocks
Jordan_matrix(c(4, 5, 6), c(2, 3, 1))
## a matrix with a 2x2 Jordan block for eval 1 and two simple 0 eval's
m <- make_mcmatrix(eigval = c(1), co = cbind(c(1,1,1,1), c(0,1,0,0)),
dim = 4, len.block = c(2))
m
m.X <- cbind(c(1,1,1,1), c(0,1,0,0), c(0,0,1,0), c(0,0,0,1))
m.X
m.J <- cbind(c(1,0,0,0), c(1,1,0,0), rep(0,4), rep(0,4))
m.J
from_Jordan(m.X, m.J) # == m
m.X %*% m.J %*% solve(m.X) # == m
all(m == from_Jordan(m.X, m.J)) && all(m == m.X %*% m.J %*% solve(m.X))
## TRUE
## which column(s) in m.X correspond to 1st Jordan block?
chain_ind(1, c(2,1,1)) # c(1, 2) since 2x2 Jordan block
## which column(s) in m.X correspond to 2nd Jordan block?
chain_ind(2, c(2,1,1)) # 3, simple eval
## which column(s) in m.X correspond to 1st and 2nd Jordan blocks?
chain_ind(c(1, 2), c(2,1,1)) # c(1,2,3)
## non-contiguous subset are ok:
chain_ind(c(1, 3), c(2,1,1)) # c(1,2,4)
## split the chains into a list of matrices
chains_to_list(m.X, c(2,1,1))
m.X %*% m.J
m %*% m.X # same
all(m.X %*% m.J == m %*% m.X) # TRUE
m %*% c(1,1,1,1) # = c(1,1,1,1), evec for eigenvalue 1
m %*% c(0,1,0,0) # gen.e.v. for eigenvalue 1
## indeed:
all( m %*% c(0,1,0,0) == c(0,1,0,0) + c(1,1,1,1) ) # TRUE
## m X = X jordan.block
cbind(c(1,1,1,1), c(0,1,0,0)) %*% cbind(c(1,0), c(1,1))
m %*% cbind(c(1,1,1,1), c(0,1,0,0))
mcompanion documentation built on Sept. 22, 2023, 5:12 p.m.
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| jordan | R Documentation |
Utilities for Jordan matrices
Description
Utility functions for work with the Jordan decompositions of matrices: create a block diagonal matrix of Jordan blocks, restore a matrix from its Jordan decomposition, locate specific chains.
Usage
Jordan_matrix(eigval, len.block)
from_Jordan(x, jmat, ...)
chain_ind(chainno, len.block)
chains_to_list(vectors, heights)
Arguments
eigval |
eigenvalues, a numeric or complex vector. |
len.block |
lengths of Jordan chains, a vector of positive integers. |
x |
generalised eigenvectors, a matrix with one column for each (generalised) eigenvector. |
jmat |
a Jordan matrix. |
chainno |
a vector of positive integers between 1 and |
... |
further arguments to pass on to |
vectors |
a matrix of generalised eigenvectors of a matrix. |
heights |
a vector of chain lengths, |
Details
Jordan_matrix creates a Jordan matrix (block-diagonal matrix
with Jordan blocks on the diagonal) whose i-th diagonal block
corresponds to eigval[i] and is of size len.block[i].
If len.block is missing, Jordan_matrix returns
diag(eigenvalues).
from_Jordan computes the matrix whose Jordan decomposition is
represented by arguments X (chains) and J (Jordan
matrix). Conceptually, the result is equivalent to XJX^{-1} but
without explicitly inverting matrices (currently the result is the
transpose of solve(t(x), t(x %*% jmat), ...)).
chain_ind computes the columns of specified Jordan chains in a
matrix of generalised eigenvectors. It is mostly internal function.
If x is a matrix whose columns are generalised eigenvectors and
the i-th Jordan chain is of length len.block[i], then this
function gives the column numbers of x containing the specified
chains.
Note that chain_ind is not able to deduce the total number of
eigenvalues. It is therefore an error to omit argument
len.block when calling it.
chains_to_list converts the matrix vectors into a list
of matrices. The i-th element of this list is a matrix whose columns
are the vectors in the i-th chain.
Value
for Jordan_matrix, a matrix with the specified Jordan blocks on
its diagonal.
for from_Jordan, the matrix with the specified Jordan
decomposition.
for chain_ind, a vector of positive integers giving the columns
of the requested chains.
for chains_to_list, a list of matrices.
Level
0
Author(s)
Georgi N. Boshnakov
Examples
## single Jordan blocks
Jordan_matrix(4, 2)
Jordan_matrix(5, 3)
Jordan_matrix(6, 1)
## a matrix with the above 3 blocks
Jordan_matrix(c(4, 5, 6), c(2, 3, 1))
## a matrix with a 2x2 Jordan block for eval 1 and two simple 0 eval's
m <- make_mcmatrix(eigval = c(1), co = cbind(c(1,1,1,1), c(0,1,0,0)),
dim = 4, len.block = c(2))
m
m.X <- cbind(c(1,1,1,1), c(0,1,0,0), c(0,0,1,0), c(0,0,0,1))
m.X
m.J <- cbind(c(1,0,0,0), c(1,1,0,0), rep(0,4), rep(0,4))
m.J
from_Jordan(m.X, m.J) # == m
m.X %*% m.J %*% solve(m.X) # == m
all(m == from_Jordan(m.X, m.J)) && all(m == m.X %*% m.J %*% solve(m.X))
## TRUE
## which column(s) in m.X correspond to 1st Jordan block?
chain_ind(1, c(2,1,1)) # c(1, 2) since 2x2 Jordan block
## which column(s) in m.X correspond to 2nd Jordan block?
chain_ind(2, c(2,1,1)) # 3, simple eval
## which column(s) in m.X correspond to 1st and 2nd Jordan blocks?
chain_ind(c(1, 2), c(2,1,1)) # c(1,2,3)
## non-contiguous subset are ok:
chain_ind(c(1, 3), c(2,1,1)) # c(1,2,4)
## split the chains into a list of matrices
chains_to_list(m.X, c(2,1,1))
m.X %*% m.J
m %*% m.X # same
all(m.X %*% m.J == m %*% m.X) # TRUE
m %*% c(1,1,1,1) # = c(1,1,1,1), evec for eigenvalue 1
m %*% c(0,1,0,0) # gen.e.v. for eigenvalue 1
## indeed:
all( m %*% c(0,1,0,0) == c(0,1,0,0) + c(1,1,1,1) ) # TRUE
## m X = X jordan.block
cbind(c(1,1,1,1), c(0,1,0,0)) %*% cbind(c(1,0), c(1,1))
m %*% cbind(c(1,1,1,1), c(0,1,0,0))
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