Reproducing Kernel Hilbert Space Methods for wide-sense
		  self-similar Processes

Reproducing Kernel Hilbert Space Methods for wide-sense self-similar Processes

Carl J. Nuzman and H. Vincent Poor

Source: Ann. Appl. Probab. Volume 11, Number 4 (2001), 1199-1219.

Abstract

It has recently been observed that wide-sense self-similar processes have a rich linear structure analogous to that of wide-sense stationary processes. In this paper, a reproducing kernel Hilbert space (RKHS) approach is used to characterize this structure. The RKHS associated with a self-similar process on a variety of simple index sets has a straightforward description, provided that the scale-spectrum of the process can be factored. This RKHS description makes use of the Mellin transform and linear self-similar systems in much the same way that Laplace transforms and linear time-invariant systems are used to study stationary processes.

The RKHS results are applied to solve linear problems including projection, polynomial signal detection and polynomial amplitude estimation, for general wide-sense self-similar processes. These solutions are applied specifically to fractional Brownian motion (fBm). Minimum variance unbiased estimators are given for the amplitudes of polynomial trends in fBm, and two new innovations representations for fBm are presented.

Primary Subjects: 60G18

Secondary Subjects: 46E22, 60G35

Keywords: Self-similar; reproducing kernel Hilbert space; Lamperti’s transformation; Mellin transform; fractional Brownian motion; detection; estimation; innovations

Full-text: Open access

PDF File (191 KB)

Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aoap/1015345400
Digital Object Identifier: doi:10.1214/aoap/1015345400
Mathematical Reviews number (MathSciNet): MR1878295
Zentralblatt MATH identifier: 1012.60043

back to Table of Contents

References

Albin, J. M. P. (1998). On extremal theory for self-similar processes. Ann. Probab. 26 743-793.

Mathematical Reviews (MathSciNet): MR99d:60049

Zentralblatt MATH: 0937.60033

Barton, R. J. and Poor, H. V. (1988). Signal detection in fractional Gaussian noise. IEEE Trans. Inform. Theory 34 943-959.

Mathematical Reviews (MathSciNet): MR90e:94007

Burnecki, K., Maejima, M. and Weron, A. (1997). The Lamperti transformation for self-similar processes. Yokohama Math. J. 44 25-42.

Mathematical Reviews (MathSciNet): MR98g:60081

Zentralblatt MATH: 0881.60040

Decreusefond, L. and ¨Ust ¨unel, A. S. (1999). Stochastic analysis of the fractional Brownian motion. Potential Anal. 10 177-214.

Mathematical Reviews (MathSciNet): MR2000b:60133

Zentralblatt MATH: 0924.60034

Goldberger, A. L. and West, B. (1987). Fractals in physiology and medicine. Yale Journal of Medicine and Biology 60 421-435.

H´ajek, J. (1962). On linear statistical problems in stochastic processes. Czechoslovak Math. J. 12 404-444.

Mathematical Reviews (MathSciNet): MR27:2070

Kailath, T. (1971). An RKHS approach to detection and estimation problems. Part I. Deterministic signals in Gaussian noise. IEEE Trans. Inform. Theory 17 530-549.

Kailath, T. and Poor, H. V. (1998). Detection of stochastic processes. IEEE Trans. Inform. Theory 44 2230-2259.

Mathematical Reviews (MathSciNet): MR99i:94017

Lamperti, J. (1962). Semi-stable stochastic processes. Trans. Amer. Math. Soc. 104 62-78.

Mathematical Reviews (MathSciNet): MR25:1575

Leland, W. E., Taqqu, M. S., Willinger, W. and Wilson, D. V. (1994). On the self-similar nature of Ethernet traffic (extended version). IEEE/ACM Trans. Networking 2 1-15.

Mandelbrot, B. B. (1965). Self-similar error clusters in communications systems and the concept of conditional stationarity. IEEE Trans. Comm. Technol. 13 71-90.

Mandelbrot, B. B. and Van Ness, J. (1968). Fractional Brownian motions, fractional noises, and applications. SIAM Rev. 10 422-437.

Mathematical Reviews (MathSciNet): MR39:3572

Zentralblatt MATH: 0179.47801

Mol can, G. M. and Golosov, J. I. (1969). Gaussian stationary processes with asymptotic power spectrum. Soviet Math. Dokl. 10 134-137.

Mathematical Reviews (MathSciNet): MR39:3580

Nuzman, C. J. (2000). The linear structure of self-similar processes. Ph. D. dissertation, Princeton Univ.

Nuzman, C. J. and Poor, H. V. (2000). Linear estimation of self-similar processes via Lamperti's transformation. J. Appl. Probab. 37 429-452.

Mathematical Reviews (MathSciNet): MR2001d:60040

Zentralblatt MATH: 0963.60034

Parzen, E. (1963). Probability density functionals and reproducing kernel Hilbert spaces. In Proceedings of the Symposium on Time Series Analysis (M. Rosenblatt, ed.). Wiley, New York.

Mathematical Reviews (MathSciNet): MR26:7119

Samorodnitsky, G. and Taqqu, M. S. (1994). Stable Non-Gaussian Random Processes: Stochastic Models with Infinite Variance. Chapman and Hall, New York.

Stewart, C. V., Moghaddam, B., Hintz, K. J. and Novak, L. M. (1993). Fractional Brownian motion models for synthetic aperture radar imagery scene segmentation. Proc. IEEE 81 1511-1521.

Weinert, H. L., ed. (1982). Reproducing Kernel Hilbert Spaces: Applications in Statistical Signal Processing. Hutchinson Ross, Stroudsburg, PA.

Willinger, W., Taqqu, M. S. and Teverovsky, V. (1999). Stock market prices and long-range dependence. Finance and Stochastics 3 1-13.

Zentralblatt MATH: 0924.90029

Wong, E. (1971). Stochastic Processes in Information and Dynamical Systems. McGraw-Hill, New York.

Wornell, G. (1991). Synthesis, analysis, and processing of fractal signals. Ph.D. dissertation, MIT.

Yazici, B. and Kashyap, R. L. (1997). A class of second-order stationary self-similar processes for 1/f phenomena. IEEE Trans. Signal Process. 45 396-410.

previous :: next