Hilbert Space of Probability Density Functions Based on Aitchison Geometry

Hilbert Space of Probability Density Functions Based on Aitchison Geometry

The set of probability functions is a convex subset of L^sup 1^ and it does not have a linear space structure when using ordinary sum and multiplication by real constants. Moreover, difficulties arise when dealing with distances between densities. The crucial point is that usual distances are not in...

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Veröffentlicht in:Acta mathematica Sinica. English series 2006-07, Vol.22 (4), p.1175-1182
Hauptverfasser: Egozcue, J. J., Díaz–Barrero, J. L., Pawlowsky–Glahn, V.
Format: Artikel
Sprache:eng
Schlagworte:
Applied mathematics
Constants
Data analysis
Density
Geometry
Hilbert space
Intervals
Mathematical analysis
Mathematical functions
Probability
Probability density functions
Random variables
Spacecraft
Studies
Transformations
Vector space
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Zusammenfassung:The set of probability functions is a convex subset of L^sup 1^ and it does not have a linear space structure when using ordinary sum and multiplication by real constants. Moreover, difficulties arise when dealing with distances between densities. The crucial point is that usual distances are not invariant under relevant transformations of densities. To overcome these limitations, Aitchison's ideas on compositional data analysis are used, generalizing perturbation and power transformation, as well as the Aitchison inner product, to operations on probability density functions with support on a finite interval. With these operations at hand, it is shown that the set of bounded probability density functions on finite intervals is a pre-Hilbert space. A Hilbert space of densities, whose logarithm is square-integrable, is obtained as the natural completion of the pre-Hilbert space.[PUBLICATION ABSTRACT]
ISSN:1439-8516
1439-7617
DOI:10.1007/s10114-005-0678-2