Abstract :
Using geometrical, algebraic, and statistical arguments, it is clarified why and when the singular value decomposition is successful in so-called subspace methods. First the concepts of long and short spaces are introduced, and a fundamental asymmetry in the consistency properties of the estimates is discussed. The model, which is associated with the short space, can be estimated consistently, but the estimates of the original data, which follow from the long space, are always inconsistent. An expression is found for the asymptotic bias in terms of canonical angles, which can be estimated from the data. This allows all equivalent reconstructions of the original signals to be described as a matrix ball, the center of which is the minimum variance estimate. Remarkably, the canonical angles also appear in the optimal weighting that is used in weighted subspace fitting approaches. The results are illustrated with a numerical simulation. A number of examples are discussed
Keywords :
matrix algebra; signal processing; state estimation; state-space methods; SVD; algebraic arguments; asymptotic bias; canonical angles; consistency properties; fundamental asymmetry; geometrical arguments; long space; matrix ball; minimum variance estimate; noisy matrices; numerical simulation; optimal weighting; short space; signal reconstruction; singular value decomposition; statistical arguments; subspace methods; weighted subspace fitting; Additive noise; Biomedical signal processing; Direction of arrival estimation; Electrocardiography; Least squares approximation; Matrix decomposition; Numerical simulation; Signal processing algorithms; Singular value decomposition; Solid modeling;
