Open AccessA New Scaling for Newton's Iteration for the Polar Decomposition and its Backward Stability
Author(s) -
Ralph Byers,
Hongguo Xu
Publication year - 2008
Publication title -
siam journal on matrix analysis and applications
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.268
H-Index - 101
eISSN - 1095-7162
pISSN - 0895-4798
DOI - 10.1137/070699895
Subject(s) - mathematics , scaling , polar decomposition , singular value decomposition , singular value , condition number , inverse , norm (philosophy) , matrix norm , rate of convergence , newton's method , convergence (economics) , scalar (mathematics) , matrix (chemical analysis) , mathematical analysis , polar , algorithm , geometry , eigenvalues and eigenvectors , channel (broadcasting) , physics , electrical engineering , materials science , quantum mechanics , astronomy , nonlinear system , economic growth , political science , law , economics , composite material , engineering
We propose a scaling scheme for Newton's iteration for calculating the polar decomposition. The scaling factors are generated by a simple scalar iteration in which the initial value depends only on estimates of the extreme singular values of the original matrix, which can, for example, be the Frobenius norms of the matrix and its inverse. In exact arithmetic, for matrices with condition number no greater than $10^{16}$, with this scaling scheme no more than 9 iterations are needed for convergence to the unitary polar factor with a convergence tolerance roughly equal to $10^{-16}$. It is proved that if matrix inverses computed in finite precision arithmetic satisfy a backward-forward error model, then the numerical method is backward stable. It is also proved that Newton's method with Higham's scaling or with Frobenius norm scaling is backward stable.
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