Browse > Article
http://dx.doi.org/10.5351/KJAS.2009.22.6.1143

Climate Prediction by a Hybrid Method with Emphasizing Future Precipitation Change of East Asia  

Lim, Yae-Ji (Department of Statistics, Seoul National University)
Jo, Seong-Il (Department of Statistics, Seoul National University)
Lee, Jae-Yong (Department of Statistics, Seoul National University)
Oh, Hee-Seok (Department of Statistics, Seoul National University)
Kang, Hyun-Suk (National Institute of Meteorological Research Korea Meteorological Administration)
Publication Information
The Korean Journal of Applied Statistics / v.22, no.6, 2009 , pp. 1143-1152 More about this Journal
Abstract
A canonical correlation analysis(CCA)-based method is proposed for prediction of future climate change which combines information from ensembles of atmosphere-ocean general circulation models(AOGCMs) and observed climate values. This paper focuses on predictions of future climate on a regional scale which are of potential economic values. The proposed method is obtained by coupling the classical CCA with empirical orthogonal functions(EOF) for dimension reduction. Furthermore, we generate a distribution of climate responses, so that extreme events as well as a general feature such as long tails and unimodality can be revealed through the distribution. Results from real data examples demonstrate the promising empirical properties of the proposed approaches.
Keywords
Canonical correlation analysis; empirical orthogonal function; climate change; precipitation; prediction;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Glahn, H. (1963). Canonical correlation and its relationship to discriminate analysis and multiple regression, Journal of the Atmospheric Sciences, 25, 23-31
2 Greene, A. M., Goddard, L. and Lall, U. (2006). Probabilistic multimodel regional temperature change projections, Journal of Climate, 19, 4326-4343   DOI   ScienceOn
3 Landman, W. A. and Goddard, L. (2002). Statistical recalibration of GCM forecasts over southern Africa using model output statistics, Journal of Climate, 15, 2038-2055   DOI   ScienceOn
4 Parzen, E. (1962). On estimation of a probability density function and mode, The Annals of Mathematical Statistics, 33, 1065-1076   DOI   ScienceOn
5 Storch, H. V. and Zwiers, F. W. (1999). Statistical Analysis in Climate Research, Cambridge
6 Wilks, D. S. (2006). Statistical Methods in the Atmospheric Sciences, Academic Press