Title :
Subspace invariance: the RO-FST and TQR-SVD adaptive subspace tracking algorithms
Author :
Rabideau, Daniel J.
Author_Institution :
Lincoln Lab., MIT, Lexington, MA, USA
fDate :
8/1/1995 12:00:00 AM
Abstract :
Subspace decomposition and tracking are quintessential ingredients in high-resolution adaptive array processing. MUSIC, minimum norm, and eigenbeamforming (projection nulling) are examples. Unfortunately, high computational complexity limits the use of subspace tracking in real-time systems. Adaptive algorithms with lower complexities have been proposed to address this limitation. The authors compare two such algorithms: TQR-SVD and fast subspace tracking (FST). Both have lower complexity than traditional approaches, with FST´s complexity being lower than TQR-SVD´s by a factor of r (the dimension of the dominant subspace). The authors show that a simplified version of FST (called RO-FST-refinement only-FST) produces the same subspace estimates as the TQR-SVD algorithm
Keywords :
adaptive signal processing; array signal processing; computational complexity; matrix decomposition; real-time systems; singular value decomposition; tracking; MUSIC; RO-FST; TQR-SVD; adaptive subspace tracking algorithms; computational complexity; decomposition; eigenbeamforming; fast subspace tracking; high-resolution adaptive array processing; minimum norm; projection nulling; real-time systems; refinement only-FST; subspace estimates; subspace invariance; Covariance matrix; Direction of arrival estimation; Distributed decision making; Integrated circuit noise; Matrix decomposition; Multiple signal classification; Partitioning algorithms; Signal processing algorithms;
Journal_Title :
Signal Processing, IEEE Transactions on
