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Linear estimation of self-similar processes via Lamperti's transformation

Published online by Cambridge University Press:  14 July 2016

Carl J. Nuzman*
Affiliation:
Princeton University
H. Vincent Poor*
Affiliation:
Princeton University
*
Postal address: Dept. of Electrical Engineering, Engineering Quadrangle, Princeton, NJ 08544 5263, USA
Postal address: Dept. of Electrical Engineering, Engineering Quadrangle, Princeton, NJ 08544 5263, USA

Abstract

Lamperti's transformation, an isometry between self-similar and stationary processes, is used to solve some problems of linear estimation of continuous-time, self-similar processes. These problems include causal whitening and innovations representations on the positive real line, as well as prediction from certain finite and semi-infinite intervals. The method is applied to the specific case of fractional Brownian motion (FBM), yielding alternate derivations of known prediction results, along with some novel whitening and interpolation formulae. Some associated insights into the problem of discrete prediction are also explored. Closed-form expressions for the spectra and spectral factorization of the stationary processes associated with the FBM are obtained as part of this development.

Type
Research Papers
Copyright
Copyright © by the Applied Probability Trust 2000 

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Footnotes

Research supported in part by the US Office of Naval Research underGrant N00014–00–1–0141, and in part by the US Department of Defense NDSEG Fellowship Program.

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