Abstract
In this paper, we present a unified approach to decomposing a special class of block tridiagonal matrices K (α ,β ) into block diagonal matrices using similarity transformations. The matrices K (α ,β )∈ Rpq× pq are of the form K (α ,β = block-tridiag[β B,A,α B] for three special pairs of (α ,β ): K (1,1), K (1,2) and K (2,2) , where the matrices A and B, A, B∈ Rp× q , are general square matrices. The decomposed block diagonal matrices (α ,β ) for the three cases are all of the form: (α ,β ) = D1 (α ,β ) ⊕ D2 (α ,β ) ⊕---⊕ Dq (α ,β ) , where Dk (α ,β ) = A+ 2cos ( θk (α ,β )) B, in which θk (α ,β ) , k = 1,2, --- q , depend on the values of α and β. Our decomposition method is closely related to the classical fast Poisson solver using Fourier analysis. Unlike the fast Poisson solver, our approach decomposes K (α ,β ) into q diagonal blocks, instead of p blocks. Furthermore, our proposed approach does not require matrices A and B to be symmetric and commute, and employs only the eigenvectors of the tridiagonal matrix T (α ,β ) = tridiag[β b, a,αb] in a block form, where a and b are scalars. The transformation matrices, their inverses, and the explicit form of the decomposed block diagonal matrices are derived in this paper. Numerical examples and experiments are also presented to demonstrate the validity and usefulness of the approach. Due to the decoupled nature of the decomposed matrices, this approach lends itself to parallel and distributed computations for solving both linear systems and eigenvalue problems using multiprocessors.
Highlights
In this paper, we present explicit similarity transformations to decompose block tridiagonal matrices K (α, β ) ∈ pq× pq of the following form: A αB B A B K (α, β ) = B A (1)β B A for some special pairs of (α, β ), where A, B ∈ p× p, into block diogonal matrices
We shall show that the transformations K (α, β ) for these three (α, β ) pairs all lead to the block diagonal matrices K (α, β ) of the following single unified form: K (α=, β ) D1 (α, β ) ⊕ D2 (α, β ) ⊕ ⊕ Dq (α, β )
The block decompositions are all based on similarity transformations with known eigenvectors of certain tridiagonal matrices and they all yield a single unified form of block diagonal matrices
Summary
We present explicit similarity transformations to decompose block tridiagonal matrices K (α , β ) ∈ pq× pq of the following form:. 2) We take this opportunity to correct the errors made in our previous paper by providing formal proof with the transformation matrix formed by the correct eigenvectors for decomposing K (2, 2) in Theorem 2. Since similarity transformations preserve all eigenvalues, the eigenvalues of the original matrix K (α , β ) , which is of size pq by pq, can be obtained from the q diagonal blocks Dk (α , β ) , each of size only p by p This block decomposition scheme provides a much more efficient means for solving eigenvalue problems with this type of coefficient matrices. The decoupled structure of the transformed matrix lends itself to parallel computation with coarse-grain parallelism
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