The dataset of local-scale variables used in this study is the monthly precipitation records of the Turkish State Meteorological Service. The selected meteorological stations provide a suitable spatial distribution of the rainfall regions (Fig. 1, Table I) of Turkey.

Fig. 1.

The rainfall regions of Turkey according to Türkes and Tatli (2011). The stations used in this study are numbered on the map, and their identifier can be found in Table I. BLS: Black Sea; NWTR: northwest Turkey; SAEG-WMED: southern Aegean and western Mediterranean; MED: Mediterranean; W-CCAN: west continental Central Anatolia; E-CCAN: east continental Central Anatolia; CEAN-CSEAN: continental eastern and southeastern Anatolia.

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The large-scale predictors needed for the study were extracted from the precipitation series simulated by the Second Generation Canadian Coupled General Circulation Model (CGCM2) of the Canadian Centre for Climate Modeling and Analysis (CCCma). For more details about the CGCM2 one may refer to the website of the CCCma (http://www.cccma. ec.gc.ca/models/models.shtm), Flato et al. (2000), or the IPCC data distribution center (http://www. mad.zmaw.de/IPCCDDC/html/ddcgcmdata.html). The atmospheric component of CGCM2 is a spectral model with triangular truncation at wave number 32 and a surface grid resolution of roughly 3.75 × 3.75° with 10 vertical levels

A logistic regression technique is used in this study to statistically downscale results from simulations of a global climate model with coarse resolution. Some definitions are needed for clarifying the question of how a logistic regression can be used as a downscaling technique. In simple logistic regression, the dependent variable (i.e., predictand) is usually dichotomous or binary, that is, the predictand can assume the value of 1(one) with a probability of P for success and the value of 0 (zero) with a probability of 1-P for failure. However, the logistic regression can also be extended to cases where the dependent variable can take more than two values, known as multinomial or polytomous (Aldrich and Nelson, 1984; Menard, 1995; Tabachnick and Fidell, 1996; Kleinbaum and Klein, 2002; Preisler and Westerling, 2007; Prasad et al., 2010). The logistic regression is more powerful than other linear regression models, and it makes no assumption on the probability distribution of the predictors. The probability distribution in question needs not to be normally distributed, linearly related or have an equal variance within each group; these restrictions are needed in the traditional linear regression applications. The relationships are derived from the so-called logit-transformation by the success probability of:

where xi(i=1,2,…,n) is the predictor and bi (i=0,1,2,…,n) is the coefficient of logistic regression. Since logistic regression estimates the probability of success over the probability of failure, the results of the analysis could be put as odd ratios in the following expression:

The logistic regression is structurally similar to the well-known multivariate linear regression, where the logits act as predictors and the predictands are natural logarithms of the success probabilities (i.e., the odds).

The coefficients are generally obtained by using the weighted Newton-Raphson algorithm. This method is attractive, because the response variables can be naturally arranged as a sequence of binary choices. For this reason, it is a very suitable approach to categorize drought events. The application steps of this method are briefly summarized below according to Tabachnick and Fidell (1996), and Kleinbaum and Klein (2002):

• 1.

  Choose initial estimates of the regression coefficients, bT=0.

• 2.

  At each iteration step k, update the coefficients,

where X and y are treated as large-scale predictors and predictands (containing zeros and ones), and Vk-1 is the weight matrix where the diagonal entries pi,k-1(1-pk-1) represent the occurrence probability. Step 2 is repeated until bk is close enough to bk-1. The estimated asymptotic covariance matrix of the coefficients is given by (XTVX)–1. The Newton-Raphson algorithm can be extended to a higher dimensional version (polytomous), and its parameters are illustrated with the vector of pk-1 in Eq. 3. The method is a multivariate regression model of the so-called conditional multinomial logistic regression.

The predictors illustrated with the matrix X are selected from the output of the simulation with the CGCM2, which is used to produce ensemble climate change projections using the IPCC's older IS92a forcing scenarios, as well as the newer SRESA2 and SRESB2 scenarios (IPCC, 2000). Note that the results of the CGCM2 are also used in the third assessment report of the IPCC (IPCC, 2001), and in the Arctic climate impact assessment.

The suggested procedure is schematically given in Figure 2. Its source code is developed in Fortran 95, and it accounts for the missing values in the data. A test based on the index, namely the accuracy or proportion of correct predictions (Murphy, 1996; Livezey, 2003), was applied for measuring the performance of the logistic models. This test is commonly used to evaluate the performance of weather forecasting in meteorology.

Fig. 2.

Schematic description of the suggested downscaling model based on polytomous logistic regression. Alpha and beta vectors shown in parentheses are the coefficients of the regression model in question.

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The drought and wet classes of 12-month SPI values are calculated from the observed precipitation values as a first stage. The probability density function (PDF) of precipitation values is the first step to estimate SPI values (one may refer to Türkeş and Tatli [2009] for a discussion on SPIs and modified-SPIs). The gamma function approach is widely used to estimate the PDF of precipitation values (e.g., Thom, 1966; McKee et al., 1993, 1995; Wilks, 1995; Guttman, 1998, 1999). In this study the cumulative distribution function (CDF) of the precipitation series is estimated by the numerical integration of fitted gamma PDF by the incomplete-gamma approach (Press et al., 1992). Twelve-month SPI values are used, but the suggested algorithm can be easily applied to other time slices of the SPI values, such as 1, 3, 6,…, -month, or more. The gamma PDF and CDF can be written as follows:

where y indicates the precipitation value, and α and β are the shape parameter and the scale parameter of the distribution, respectively. The quantity Γ(·) is the gamma function defined by

An improved method suggested by Bowman and Shenton (1988) was applied for estimating the shape parameter resulting from the use of an iterative sixth order polynomial. The scale parameter is then calculated by dividing the long-term mean of precipitation values by the shape parameter, β=y¯/α

At the second stage, SPI values are classified according to Table II. At the third stage, the dichotomous classes of drought and wet conditions are grouped into two classes, namely high and low SPIs treated as binary values (ones and zeros) represented by wet and dry classes in Figure 2. This stage involves a simple logistic regression which classifies the occurrence probabilities of wet and dry cases.

Finally, the fourth stage involves a polytomous logistic regression. In Figure 2, the vectors given in the parentheses represented by alphas and betas indicate the coefficients of the specific logistic regression. The dependent variable can take four dichotomous values numbered as (k=0, 1, 2, 3), representing the drought classes as shown on the left and right sides of Figure 2. To further clarify this step, assume we wish to estimate the occurrence probability of a moderately dry class. By applying the vector of coefficients, the occurrence probabilities are calculated as:

After calculating the occurrence probabilities of the entire dry classes by using Eq. 6, the drought class of maximum probability is selected as the downscaled-class for the specific station.

In order to measure the performance of the suggested model, the index of forecast accuracy or proportion of correct predictions (PC) was calculated between the output of the downscaling model-based control and the observed SPI classes for the period 1970-2000. For verifying multi-category forecasts, the method starts with frequencies of the forecast and observations in various bins, as given in Table III. A perfect forecast system should have values of non-zero elements only along the diagonal, and values of 0 (zero) for all entries off the diagonal. The off-diagonal elements give information about the specific nature of the forecast errors (Murphy, 1996; Livezey, 2003). The value of PC for the selected station is calculated as:

PC ranges from 0 to 1. If it assumes a value, close to 1, this indicates a high forecasting performance.

According to the extremely dry conditions obtained from the observed rainfall totals, the long-term (climatological) probabilities display a zonal-pattern gradient from the Mediterranean to the Black Sea basins. Maximum probabilities are found in the warm and dry southern parts of the continental Mediterranean (CMED) rainfall regions, in which the areas of the Turkish-Syrian border are located (Fig. 4a).

According to the logistic model constructed by the predictors from the control climate simulations (Fig. 5a), the probabilities of extremely dry conditions will increase in approximately 10% of the cases. These downscaling results for the Mediterranean (MED) and CMED rainfall regions agree well with the observations, as seen in Figure 4a. The probabilities of extremely dry conditions obtained from the observed values are around 1%, in spite of the results of the logistic model based on the control scenario indicate around 20% in the country's sub-regions of the western Black Sea basin (Fig. 5a). Additionally, the results show that the probabilities do not change sharply in the regions of the Marmara Transition (MRT) and the Mediterranean Transition (MEDT).

The probability patterns of downscaling models based on the IPCC SRESS A2 and B2 (Figs. 6 and 7, respectively) resemble each other. Furthermore, the estimated probabilities of extremely dry conditions in the Black Sea (BLS) region seem similar to the probabilities obtained by the downscaling-model based on the control simulations. However, the estimated probabilities of extremely dry conditions in the MED and CMED regions are 10% higher than the values obtained from the control simulation (Figs. 6a and 7a). The estimated probabilities for the eastern sub-regions of the BLS and northeastern Anatolia are similar in magnitude and spatial distribution.

Fig. 6.

Spatial distribution of the long-term probabilities of SPIs of the downscaling model based on the IPCC SRES A2.

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Fig. 7.

Spatial distribution of the long-term probabilities of SPIs of the downscaling model based on the IPCC SRES B2.

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Although the observed probabilities of severely dry conditions are relatively low (about 2%), they increase from the MED and CMED to the northern part of the country. Furthermore, the probability values reach 4% in the eastern BLS and northern Anatolia sub-regions of the Anatolian Peninsula, even though the probability values of extremely dry conditions are low (Fig. 4b).

The logistic control model produces somewhat different patterns of probabilities when compared to observations, except for the MRT rainfall region (Fig. 5b). Conversely, results of the logistic model based on the IPCC SRES A2 and B2 scenarios show patterns similar to the observed probabilities obtained from the severely dry scenario (Figs. 6b and 7b).

The probabilities of a severely dry scenario obtained from the observations have a 2-4% interval, with some exceptions as seen in the MED and CMED rainfall regions (Fig. 4b), where the probabilities of a severely dry scenario show a negative trend. The results of the logistic model based on the IPCC SRES A2 have somewhat higher probabilities than those obtained from the IPCC SRES B2 (Figs. 6b and 7b).

The probabilities of having 12-month SPI values of moderately dry class increase in rainfall regions MED and BLS, where the probabilities observed are about 4-5% (Fig. 4c). The probabilities observed in the western and eastern BLS sub-regions vary from 7 to 9%, respectively.

The results of the logistic model based on the control scenario show that the pattern of higher probabilities has detailed spatial features, though some small probabilities are also observed (Fig. 5c). According to the logistic model with predictors from the IPCC SRES A2 and B2 scenarios, the patterns of probabilities of moderately dry conditions have a positive trend (Figs. 6c and 7c).

The 12-month SPI values from observations in Turkey are mostly in the near normal class, since the climatological probabilities are generally changing from 60 to 70% (Fig. 4d). As a result, this class could be referred to as reference class, which has a probability of being observed at least in 60% of the meteorological stations.

The probabilities of the logistic model based on the control scenario are in the near normal class, partially decreasing in the BLS basin. However, the patterns show that probabilities increase in the regions of the MRT and continental eastern Anatolia (CEAN) (Fig. 5d), where the probabilities observed are around 80% or more.

The results obtained from the logistic model based on the IPCC SRES A2 and B2 scenarios are significantly similar, and related to the results obtained from the control scenario (Figs. 6d and 7d). According to the downscaling results, it can be expected that the near normal class probability will increase about 10% as compared to its present values.

In Figure 4e, the probabilities of moderately wet conditions have a negative gradient from the sub-rainfall regions of MED, MEDT and CMED to the BLS basin. Some of the minimum probabilities are observed on the coasts of the BLS basin, whereas the maximum values are only obtained in the CMED regions. The sub-regions of western and eastern BLS and CEAN are exceptions, since the logistic model based on the control scenario simulates very small probabilities of moderately wet conditions (Fig. 6e). The maximum probabilities are generally observed in the rainfall regimes of the MED and CMED, whereas the probabilities of the logistic model based on the control scenario decrease here and increase in the eastern BLS basin and north-eastern Anatolia.

The results of the logistic model based on the IPCC SRES A2 and B2 show similarities with the control scenario (Figs. 6e and 7e). These similarities may be seen in the probability patterns of moderately wet conditions, which decrease in the southern and western regions of the country.

Accordingly, it can be expected that the probabilities of moderately wet conditions will increase in the BLS basin and in the northeastern continental regions of the country. Furthermore, the maximum probabilities of moderately wet conditions are found in the eastern BLS basin for the logistic model based on the IPCC SRES A2, and in northeastern Anatolia for the model based on the IPCC SRES B2.

The probabilities of the very wet class range from 3% in the CEAN region to 4% in the Aegean, Mediterranean and Black Sea regions (Fig. 4f). The maximum probabilities of very wet conditions are about 5% in northeastern Anatolia. The probabilities are smaller for the logistic model based on the control scenario (Fig. 5f). The probabilities in the Black Sea basin, middle-northern parts of the CCAN and northeastern Anatolia are nearly 1% and close to 0% for the rest of the country.

The results obtained from logistic models based on the IPCC SRES A2 and B2 are consistent with the control simulations, in which the probabilities of very wet conditions are expected to be below 1% in the majority of the country (Figs. 6f and 7f). Both models show that the maximum probabilities are seen in parts of the northern Thrace, and in the sub-regions of the eastern and middle Black sea basin.

The probabilities of extremely wet conditions from observations are small in magnitude and vary from 0 to 2%. Maximum probabilities are evident over some limited areas of the eastern Black Sea basin, northeastern Anatolia and western Mediterranean coasts (Fig. 4g). According to the results of the logistic model based on the control scenario, except in the sub-regions of the western Black Sea basin, the probabilities are very small (Fig. 5g). In addition, the results of logistic models based on the IPCC SRES A2 and B2 agree with the results of the logistic model based on the control scenario, indicating that in the future, probabilities of extremely wet conditions will decrease in the entire country (Figs. 6g and 7g).