• Introduction.
• The statistical characterisation of time series.
• The change-point search in time-series analysis.
• Final change-point determination and test of randomness of the derived homogeneous sequences.
• Example. The annual averages of the air temperature 1908-1995 at Casablanca (Cuba).
• Conclusion.
• References.
• Tables.
• Annex.

Conclusions

From our results, three main conclusions may be emphasised.

1. On the statistical point of view, the logic and improvement of the way followed for the change-point search has ensured a complete account of the information involved in the rank analysis of the series and has avoided biases resulting from test misuses.

In particular, for testing randomness against serial correlation, the circular and non circular rank serial correlation test statistic involving both exactly the same information, they have thus the same power efficiency. However, with its symmetric distribution close to the normal one, the first test statistic avoids the complexity of distribution due to lack of symmetry of the non circular one (Bartels 1982).

On the other hand, an efficient answer has been given to the problem raised by Easterling and Peterson (1995), concerning the power limits of the methodology encountered when neglecting small discontinuities in the series. In addition, when randomness is ascertained, testing the fit of any particular distribution function, the normal one included, allows, with an increased power, further investigations on the properties of the series.

For instance, though this was not the case here, the detection of outliers in random groups with testing normality, makes possible the determination of consecutive change-points separated by only one element.

2. As discontinuities may eventually have a non climatic origin, verification of an eventual connection in the acquisition data process has always to be made, though this operation has preferably to be made before a climate instability investigation. The two phenomena being independent, the effect may be either an amplifying or a damping one depending of their relative importance (Sneyers, 1997, 1998, Sneyers et al., 1998).

3. The existence of a chaotic evolution of the climate at all scales may theoretically be explained by the existence of situations of indetermination in the day to day evolution of the General atmospheric circulation (Sneyers 1997). It follows, that eventual man made effects on this evolution may only introduce modifications in this evolution. As this effect may, here also, have either an amplifying or a damping down effect, the problem of an eventual man made origin (observational inhomogeneities included) reduces in each case to solving this question with appropriate means.