In mathematics, a Carleman matrix is a matrix used to convert function composition into matrix multiplication.
It is often used in iteration theory to find the continuous iteration of functions which cannot be iterated by pattern recognition alone.
Other uses of Carleman matrices occur in the theory of probability generating functions, and Markov chains.
The Carleman matrix of an infinitely differentiable function
is defined as: so as to satisfy the (Taylor series) equation: For instance, the computation of
by simply amounts to the dot-product of row 1 of
with a column vector
in the next row give the 2nd power of
: and also, in order to have the zeroth power of
, we adopt the row 0 containing zeros everywhere except the first position, such that Thus, the dot product of
with the column vector
yields the column vector
, i.e., A generalization of the Carleman matrix of a function can be defined around any point, such as: or
This allows the matrix power to be related as: If we set
we have the Carleman matrix.
then we know that the n-th coefficient
must be the nth-coefficient of the taylor series of
(It's important to note that this is not an orthornormal basis) If
is an orthonormal basis for a Hilbert Space with a defined inner product
we have the analogous for Fourier Series.
represent the carleman coefficient and matrix in the fourier basis.
Because the basis is orthogonal, we have.
which is Carleman matrices satisfy the fundamental relationship which makes the Carleman matrix M a (direct) representation of
denotes the composition of functions
Other properties include: The Carleman matrix of a constant is: The Carleman matrix of the identity function is: The Carleman matrix of a constant addition is: The Carleman matrix of the successor function is equivalent to the Binomial coefficient: The Carleman matrix of the logarithm is related to the (signed) Stirling numbers of the first kind scaled by factorials: The Carleman matrix of the logarithm is related to the (unsigned) Stirling numbers of the first kind scaled by factorials: The Carleman matrix of the exponential function is related to the Stirling numbers of the second kind scaled by factorials: The Carleman matrix of exponential functions is: The Carleman matrix of a constant multiple is: The Carleman matrix of a linear function is: The Carleman matrix of a function
is: The Carleman matrix of a function
is: The Bell matrix or the Jabotinsky matrix of a function
is defined as[1][2][3] so as to satisfy the equation These matrices were developed in 1947 by Eri Jabotinsky to represent convolutions of polynomials.
[4] It is the transpose of the Carleman matrix and satisfy
which makes the Bell matrix B an anti-representation of