Least-Squares Approximation by Elements from Matrix Orbits Achieved by Gradient Flows on Compact Lie Groups

C. K. Li; Y. T. Poon; T. Schulte-Herbrueggen

doi:10.1090/S0025-5718-2010-02450-0

Least-Squares Approximation by Elements from Matrix Orbits Achieved by Gradient Flows on Compact Lie Groups

Numerical Analysis 2013-01-07 v1 Dynamical Systems Optimization and Control Quantum Physics

Authors: C. K. Li , Y. T. Poon , T. Schulte-Herbrueggen

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Abstract

Let $S(A)$ denote the orbit of a complex or real matrix $A$ under a certain equivalence relation such as unitary similarity, unitary equivalence, unitary congruences etc. Efficient gradient-flow algorithms are constructed to determine the best approximation of a given matrix $A_0$ by the sum of matrices in $S(A_1), ..., S(A_N)$ in the sense of finding the Euclidean least-squares distance $\min \{\|X_1+ ... + X_N - A_0\|: X_j \in S(A_j), j = 1, >..., N\}.$ Connections of the results to different pure and applied areas are discussed.

Keywords

euclidean distance and geometry function approximation matrix algorithms

Cite

@article{arxiv.0812.1817,
  title  = {Least-Squares Approximation by Elements from Matrix Orbits Achieved by Gradient Flows on Compact Lie Groups},
  author = {C. K. Li and Y. T. Poon and T. Schulte-Herbrueggen},
  journal= {arXiv preprint arXiv:0812.1817},
  year   = {2013}
}

Least-Squares Approximation by Elements from Matrix Orbits Achieved by Gradient Flows on Compact Lie Groups

Abstract

Keywords

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