Block matrix pseudoinverse is a formula of pseudoinverse of a partitioned matrix. This is useful for decomposing or approximating many algorithms updating parameters in signal processing, which are based on least squares method.
Derivation
Consider a column-wise partitioned matrix::
If the above matrix is full rank, the pseudoinverse matrices of it and its transpose are as follows.::The pseudoinverse requires "(n+p)"-square matrix inversion.
To reduce complexity and introduce parallelism, we derive the following decomposed formula.From a block matrix inverse, we can have::where orthogonal projection matrices are defined by::
Interestingly, from the idempotence of projection matrix, we can verify that the pseudoinverse of block matrix consists of pseudoinverse of projected matrices:::
Thus, we decomposed the block matrix pseudoinverse into two submatrix pseudoinverses, which cost "n"- and "p"-square matrix inversions, respectively.
Application to least squares problems
Given the same matrices as above, we consider the following least squares problems, whichappear as multiple objective optimizations or constrained problems in signal processing.Eventually, we can implement a parallel algorithm for least squares based on the following results.
Column-wise partitioning in over-determined least squares
Suppose a solution solves an over-determined system::
Using the block matrix pseudoinverse, we have:Therefore, we have a decomposed solution::
Row-wise partitioning in under-determined least squares
Suppose a solution solves an under-determined system::
The minimum-norm solution is given by:
Using the block matrix pseudoinverse, we have:
Comments on matrix inversion
Instead of , we need to calculate directly or indirectly
:
In a dense and small system, we can use singular value decomposition, QR decomposition, or Cholesky decomposition to replace the matrix inversions with numerical routines. In a large system, we may employ iterative methods such as Krylov subspace methods.
Considering parallel algorithms, we can compute and in parallel. Then, we finish to compute and also in parallel.
Proof of block matrix inversion
Let a block matrix be:We can get an inverse formula by combining the previous results in [ [http://ccrma.stanford.edu/~jos/lattice/Block_matrix_decompositions.html Block matrix decompositions] ] .:where and , respectively, Schur complements of and , are defined by , and . This relation is derived by using Block TriangularDecomposition. It is called "simple block matrix inversion." [ [http://ieeexplore.ieee.org/xpls/abs_all.jsp?isnumber=30419&arnumber=1399280&count=249&index=181 S. Jo, S. W. Kim and T. J. Park, "Equally constrained affine projection algorithm," "in Conference Record of the Thirty-Eighth Asilomar Conference on Signals, Systems and Computers," vol. 1, pp. 955-959, Nov. 7-10, 2004.] ]
Now we can obtain the inverse of the symmetric block matrix: ::::Since the block matrix is symmetric, we also have:
Then, we can see how the Schur complements are connected to the projection matrices of the symmetric, partitioned matrix.
Notes and references
External links
* [http://www.ee.ic.ac.uk/hp/staff/dmb/matrix/intro.html The Matrix Reference Manual] by [http://www.ee.ic.ac.uk/hp/staff/dmb/dmb.html Mike Brookes]
* [http://www.csit.fsu.edu/~burkardt/papers/linear_glossary.html Linear Algebra Glossary] by [http://www.csit.fsu.edu/~burkardt/ John Burkardt]
* [http://2302.dk/uni/matrixcookbook.html The Matrix Cookbook] by [http://2302.dk/uni/ Kaare Brandt Petersen]