Solar apparent radius variability: a new statistical approach to astrolabe multisite observations

Solar apparent radius variability: a new statistical approach to astrolabe multisite observations

The results of the analysis of solar diameter measurements obtained by means of the astrolabe have been inconclusive so far. Temporal variations are found, but they differ in amplitude and phase. This paper presents the results of a new statistical approach to compare and analyse the astrolabe data...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 369; no. 1; pp. 83 - 88
Main Authors: Badache-Damiani, C., Rozelot, J. P.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Publishing Ltd 11-06-2006
Blackwell Science
Oxford University Press
Subjects:
Astronomy
Comparative analysis
Earth, ocean, space
Exact sciences and technology
instrumentation: miscellaneous
Measurement
methods: data analysis
methods: statistical
Stars & galaxies
Sun: oscillations
Sun: oscillations
methods: statistical
instrumentation: miscellaneous
methods: data analysis
Correlation coefficient
Random noise
Variability
Astrolabes
Periodicity
Time series
Irradiance
Time variation
Cross correlations
Persistence
Diameter
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Summary:The results of the analysis of solar diameter measurements obtained by means of the astrolabe have been inconclusive so far. Temporal variations are found, but they differ in amplitude and phase. This paper presents the results of a new statistical approach to compare and analyse the astrolabe data obtained during the period 1998–2003 in Brazil, Chile, France and Turkey. We show that different time series can be considered as extracted from the same statistical population following the Gaussian law. As following on a variographic analysis, the series do not seem to be autocorrelated at small scale (40 d) and present the characteristics of a highly disorganized phenomenon. At medium scale (6 yr), a 1-yr periodicity can be seen. It could be the residual trace of a temporal latitudinal variability. At large scale (up to 30 yr, using only French and Chilean data available, respectively, from 1975 and 1990), a faint 11-yr component in the signal can be pointed out. As an 11-yr periodicity has been found in the stratospheric data, we have explored the possibility of a relationship between the measured radii and stratospheric phenomena. This would explain the discrepancy in amplitudes, the sign of the crossed correlation coefficients, and the apparent disorganized behaviour of the data. Therefore, a complementary non-determinist analysis has been done in order to distinguish a chaotic signal from a random noise. The Hurst exponent establishes the persistence of the series. It can be concluded that the solar measurements from astrolabes are not purely randomly distributed, but show the character of a deterministic series for which (i) the observations need to be far more accurate, as it is only possible if obtained from space or in real-time together with a seeing monitor; (ii) supposing that it is indeed possible to extract a solar component, data must be studied considering their heliographic latitude and (iii) data show the variability of the upper atmospheric conditions (maybe Quasi-Biennial Oscillations) and the stratospheric 11-yr periodicity, for which the modulation is caused by the solar irradiance.
Bibliography:istex:D5289BFC677C98B8E936B2F7407B65F68C948183
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ISSN:0035-8711
1365-2966
DOI:10.1111/j.1365-2966.2006.10248.x