论文信息 - Power spectrum reduction by optimal Hankel norm approximation of the phase of the outer spectral factor

Power spectrum reduction by optimal Hankel norm approximation of the phase of the outer spectral factor

A new approach to stochastic processes power spectrum reduction, based on Akaike's canonical correlation between the process past and future, is developed. As a first result, the correlation between the canonical past and the canonical future is given its precise functional-analytic interpretation as the Hankel operator generated lay the all-pass function characterizing the phase of the process outer spectral factor. The canonical correlation coefficients turn out to he nothing else but the singular values of this Hankel operator. Next, the all-pass function characterizing the phase of the outer spectral factor is reduced using the optimal Hankel-norm procedure of Adamjan, Arov, and Krein. The reduction of the all-pass phase function is implemented with the safeguards necessary for the magnitude information to be carried all the way through. This involves Bode's relations between the gain and the phase of an outer function, Nehari's extension, and the winding number of the all-pass phase function which is itself shown to be related to the definition of the past and the future. Finally, the net result is a reduced-order, outer spectral factor that matches the high-order spectral factor, fairly well.

J. Helton | Edmond A. Jonckheere

[1] Philip Hartman,et al. On completely continuous Hankel matrices , 1958 .

[2] H. Akaike. Markovian Representation of Stochastic Processes by Canonical Variables , 1975 .

[3] E. Jonckheere,et al. Spectral factor reduction by phase matching: the continuous-time single-input single-output case† , 1985 .

[4] K. Glover. All optimal Hankel-norm approximations of linear multivariable systems and their L, ∞ -error bounds† , 1984 .

[5] T. Kailath,et al. An innovations approach to least-squares estimation--Part VI: Discrete-time innovations representations and recursive estimation , 1973 .

[6] Stochastic balancing and approximation - Stability and minimality , 1983 .

[7] Z. Nehari. On Bounded Bilinear Forms , 1957 .

[8] U. Desai,et al. A realization approach to stochastic model reduction and balanced stochastic realizations , 1982, 1982 21st IEEE Conference on Decision and Control.

[9] B. Moore. Principal component analysis in linear systems: Controllability, observability, and model reduction , 1981 .

[10] Eigenvalue and generalized eigenvalue formulations for Hankel norm reduction directly from polynomial data , 1984, The 23rd IEEE Conference on Decision and Control.

[11] M. Kreĭn,et al. ANALYTIC PROPERTIES OF SCHMIDT PAIRS FOR A HANKEL OPERATOR AND THE GENERALIZED SCHUR-TAKAGI PROBLEM , 1971 .

[12] Y. Genin,et al. On the role of the Nevanlinna–Pick problem in circuit and system theory† , 1981 .