Title :
An Approximate Inverse-Power Algorithm for Adaptive Extraction of Minor Subspace
Author :
Feng, Da-Zheng ; Zheng, Wei Xing
Author_Institution :
Xidian Univ., Xi´´an
fDate :
7/1/2007 12:00:00 AM
Abstract :
This correspondence develops a novel and efficient algorithm to recursively extract multiple minor components from an N-dimensional vector sequence. This algorithm is of computational complexity O(N2)and obtained by approximating the well-known inverse-power iteration in conjunction with Galerkin method. Moreover, the convergence speed of the proposed algorithm is faster than that of the stochastic gradient-based algorithms with complexity O(Ngamma), where gamma is the number of minor components. Global convergence of the proposed algorithm is established. Unlike the classical recursive-least-squares-type algorithms (Ljung and Ljung, Automatica, 1985), it is shown by simulations that the proposed algorithm may have good numerical stability over a very large data sequence due to no use of the well-known matrix inversion lemma.
Keywords :
Galerkin method; adaptive signal processing; computational complexity; inverse problems; iterative methods; least squares approximations; matrix inversion; numerical stability; recursive estimation; stochastic processes; Galerkin method; N-dimensional vector sequence; adaptive minor subspace extraction; approximate inverse-power algorithm; computational complexity; global convergence; inverse-power iteration method; matrix inversion lemma; numerical stability; recursive-least-squares-type algorithms; stochastic gradient-based algorithms; Adaptive signal processing; Autocorrelation; Computational complexity; Convergence; Least squares approximation; Moment methods; Numerical stability; Radar tracking; Signal processing algorithms; Stochastic processes; Approximate inverse-power iteration; Galerkin method; global convergence; minor subspace; numerical instability;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2007.894381
