Dynamic-Stochastic Model for Atmospheric Drought Forecasting in Uzbekistan

Arushanov ML*; Eshmuratova GSH

**Arushanov ML* and Eshmuratova GSH**

Volume5-Issue8
Dates: Received: 2024-07-15 | Accepted: 2024-08-06 | Published: 2024-08-07
Pages: 901-905

Abstract

This paper presents a one-month lead-time predictive model of atmospheric drought developed at the Scientific Research Hydrometeorological Institute. The model is based on a dynamic-stochastic approach to constructing a regression predictive equation. From the set of existing methods for constructing regression equations, the method based on the characteristic roots (eigenvalues) of the correlation matrix, including the predict and column and predictor columns (extended matrix) was applied.

The standardized drought index SPI serves as the predict and, while the predictors are the average monthly precipitation for the 3 months preceding the forecast month, the average monthly value of variations in solar activity (Wolf numbers) and the average monthly value of the Southern Oscillation index for the month preceding the forecast.

The predictors were selected based on mutual correlation and applied time series analyses between the aridity index SPI and the indicated heliogeophysical values. The performed estimates of the investigated dependence of the aridity index SPI on the state of solar activity, the influence of El Niño (La Niña) and precipitation preceding the forecast date showed their high correlation.

Estimates of the accuracy of the SPI forecast with a monthly advance lead time for the territory of Uzbekistan, performed on an independent sample, were quite high, which was the basis for the introduction of this model into the operational work of the hydrometeorological service of Uzbekistan (Uzhydromet).

FullText HTML FullText PDF DOI: 10.37871/jbres1969

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How to cite this article

Arushanov ML, Eshmuratova GSH. Dynamic-Stochastic Model for Atmospheric Drought Forecasting in Uzbekistan. J Biomed Res Environ Sci. 2024 Aug 07; 5(8): 901-905. doi: 10.37871/jbres1969, Article ID: JBRES1969, Available at: https:// www.jelsciences.com/articles/jbres1969.pdf

Subject area(s)

Atmospheric Chemistry

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