diagonalisation BrE
diagonalization AmE

Diagonalisation depends upon being able to prove that multiplication is a total function (and in the earlier versions of the result, addition also).

Circulant determinants were first encountered in nineteenth century mathematics, and the consequence of their diagonalisation drawn.

Clearly any such dominating set is unbounded, so is at most , and a diagonalisation argument shows that .

We can strengthen the above to the case where all the operators merely commute with their adjoint; in this case we remove the term "orthogonal" from the diagonalisation.

If "G" were not compact, but were abelien, then diagonalisation is not achieved, but we get a unique "continuous" decomposition of "H" into 1-dimensional invariant subspaces.

In outline, the key to Willard's construction of his system is to formalise enough of the Gödel machinery to talk about provability internally without being able to formalise diagonalisation.

Then if "G" were compact then there is a unique decomposition of "H" into a countable direct sum of finite dimensional, irreducible, invariant subspaces (this is essentially diagonalisation of the family of operators ).

If X is a Hilbert space and T is a normal operator, then a remarkable result known as the spectral theorem gives an analogue of the diagonalisation theorem for normal finite-dimensional operators (Hermitian matrices, for example).

BigDFT implements density functional theory by solving the Kohn-Sham equations describing the electrons in a material, expanded in a Daubechies wavelet basis set and using a self-consistent direct minimization or Davidson diagonalisation methods to determine the energy minimum.

Cantor's diagonal argument, also called the diagonalisation argument, the diagonal slash argument or the diagonal method, was published in 1891 by Georg Cantor as a mathematical proof that there are infinite sets which cannot be put into one-to-one correspondence with the infinite set of natural numbers.

This can be viewed as a block diagonalization of T.

They are obtained by individual matrix diagonalization for each J value.

The first step is to find a matrix in which the technique of diagonalization can be applied.

With diagonalization, it is often possible to translate to and from eigenbases.

Then, the simultaneous diagonalization of those two matrices is realized.

The proof is essentially based on a diagonalization argument.

Diagonalization typically involves either raw data, percentages, means or residuals.

There exists a language (the proof uses diagonalization technique).

Carrying out the diagonalization produces the Onsager free energy.

Table diagonalization, a form of data reduction used to make interpretation of tables and charts easier.

This procedure is impractical given its high computational cost: for each space, a diagonalization of the true Hamiltonian must be performed.

This is done using a technique called "diagonalization" (so-called because of its origins as Cantor's diagonal argument).

The ground state for the superblock is obtained using the Lanczos algorithm of matrix diagonalization.

Another approach is numerical matrix diagonalization.

Given the diagonalizations of the submatrices, calculated above, how do we find the diagonalization of the original matrix?

One can complete the diagonalization of "T" by selecting an orthonormal basis of the kernel.

Once the diagonalization is completed, one can then compute the THz absorption analytically.

Table diagonalization, whereby rows and columns of tables are re-arranged to make patterns easier to see (refer to the diagram).

The formal machinery of this proof is wholly elementary except for the diagonalization that the diagonal lemma requires.

In mathematics, diagonalization may refer to:

For numerical simulation of this model, an algorithm of exact diagonalization is presented in this paper.

This corresponds to eigen modes solutions using iterative techniques, as opposed to diagonalization of the entire matrix.

Diagonalization is the process of finding a corresponding diagonal matrix for a diagonalizable matrix or linear map.

Diagonalization can be used to compute the powers of a matrix A efficiently, provided the matrix is diagonalizable.

This algorithm is a stripped-down version of the Jacobi transformation method of matrix diagonalization.