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Non-linear variability in geophysics: scaling and fractals

consequences of broken symmetry -here parity-is studied. In this model, turbulence is dominated by a hierarchy of helical (corkscrew) structures. The authors stress the unique features of such pseudo-scalar cascades as well as the extreme nature of the resulting (intermittent) fluctuations. Intermit...

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Detalles Bibliográficos
Autores principales: Schertzer, D, Lovejoy, S
Lenguaje:eng
Publicado: Springer 1991
Materias:
Acceso en línea:https://dx.doi.org/10.1007/978-94-009-2147-4
http://cds.cern.ch/record/2006551
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author Schertzer, D
Lovejoy, S
author_facet Schertzer, D
Lovejoy, S
author_sort Schertzer, D
collection CERN
description consequences of broken symmetry -here parity-is studied. In this model, turbulence is dominated by a hierarchy of helical (corkscrew) structures. The authors stress the unique features of such pseudo-scalar cascades as well as the extreme nature of the resulting (intermittent) fluctuations. Intermittent turbulent cascades was also the theme of a paper by us in which we show that universality classes exist for continuous cascades (in which an infinite number of cascade steps occur over a finite range of scales). This result is the multiplicative analogue of the familiar central limit theorem for the addition of random variables. Finally, an interesting paper by Pasmanter investigates the scaling associated with anomolous diffusion in a chaotic tidal basin model involving a small number of degrees of freedom. Although the statistical literature is replete with techniques for dealing with those random processes characterized by both exponentially decaying (non-scaling) autocorrelations and exponentially decaying probability distributions, there is a real paucity of literature appropriate for geophysical fields exhibiting either scaling over wide ranges (e. g. algebraic autocorrelations) or extreme fluctuations (e. g. algebraic probabilities, divergence of high order statistical moments). In fact, about the only relevant technique that is regularly used -fourier analysis (energy spectra) -permits only an estimate of a single (power law) exponent. If the fields were mono-fractal (characterized by a single fractal dimension) this would be sufficient, however their generally multifractal character calls for the development of new techniques.
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spelling cern-20065512021-04-21T20:21:55Zdoi:10.1007/978-94-009-2147-4http://cds.cern.ch/record/2006551engSchertzer, DLovejoy, SNon-linear variability in geophysics: scaling and fractalsOther Fields of Physicsconsequences of broken symmetry -here parity-is studied. In this model, turbulence is dominated by a hierarchy of helical (corkscrew) structures. The authors stress the unique features of such pseudo-scalar cascades as well as the extreme nature of the resulting (intermittent) fluctuations. Intermittent turbulent cascades was also the theme of a paper by us in which we show that universality classes exist for continuous cascades (in which an infinite number of cascade steps occur over a finite range of scales). This result is the multiplicative analogue of the familiar central limit theorem for the addition of random variables. Finally, an interesting paper by Pasmanter investigates the scaling associated with anomolous diffusion in a chaotic tidal basin model involving a small number of degrees of freedom. Although the statistical literature is replete with techniques for dealing with those random processes characterized by both exponentially decaying (non-scaling) autocorrelations and exponentially decaying probability distributions, there is a real paucity of literature appropriate for geophysical fields exhibiting either scaling over wide ranges (e. g. algebraic autocorrelations) or extreme fluctuations (e. g. algebraic probabilities, divergence of high order statistical moments). In fact, about the only relevant technique that is regularly used -fourier analysis (energy spectra) -permits only an estimate of a single (power law) exponent. If the fields were mono-fractal (characterized by a single fractal dimension) this would be sufficient, however their generally multifractal character calls for the development of new techniques.Springeroai:cds.cern.ch:20065511991
spellingShingle Other Fields of Physics
Schertzer, D
Lovejoy, S
Non-linear variability in geophysics: scaling and fractals
title Non-linear variability in geophysics: scaling and fractals
title_full Non-linear variability in geophysics: scaling and fractals
title_fullStr Non-linear variability in geophysics: scaling and fractals
title_full_unstemmed Non-linear variability in geophysics: scaling and fractals
title_short Non-linear variability in geophysics: scaling and fractals
title_sort non-linear variability in geophysics: scaling and fractals
topic Other Fields of Physics
url https://dx.doi.org/10.1007/978-94-009-2147-4
http://cds.cern.ch/record/2006551
work_keys_str_mv AT schertzerd nonlinearvariabilityingeophysicsscalingandfractals
AT lovejoys nonlinearvariabilityingeophysicsscalingandfractals