Abstract
Climate change information required for impact studies is of a much finer scale than that provided by Global circulation models (GCMs). This paper presents an application of partial least squares (PLS) regression for downscaling GCMs output. Statistical downscaling models were developed using PLS regression for simultaneous downscaling of mean monthly maximum and minimum temperatures (T max and T min) as well as pan evaporation to lake-basin scale in an arid region in India. The data used for evaluation were extracted from the NCEP/NCAR reanalysis dataset for the period 1948–2000 and the simulations from the third-generation Canadian Coupled Global Climate Model (CGCM3) for emission scenarios A1B, A2, B1, and COMMIT for the period 2001–2100. A simple multiplicative shift was used for correcting predictand values. The results demonstrated that the downscaling method was able to capture the relationship between the premises and the response. The analysis of downscaling models reveals that (1) the correlation coefficient for downscaled versus observed mean maximum temperature, mean minimum temperature, and pan evaporation was 0.94, 0.96, and 0.89, respectively; (2) an increasing trend is observed for T max and T min for A1B, A2, and B1 scenarios, whereas no trend is discerned with the COMMIT scenario; and (3) there was no trend observed in pan evaporation. In COMMIT scenario, atmospheric CO2 concentrations are held at year 2000 levels. Furthermore, a comparison with neural network technique shows the efficiency of PLS regression method.
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1 Introduction
Information concerning spatio-temporal patterns of temperature and their variability is necessary to model various surface processes at global and local scales in disciplines like hydrology, anthropology, agriculture, forestry, environmental engineering, and climatology (Anandhi et al. 2009). General circulation models (GCMs), representing physical processes in the atmosphere, ocean, cryosphere, and land surface, are the most advanced tools currently available to simulate time series of climate variables for the world, accounting for the effects of the concentration of greenhouse gases in the atmosphere and to obtain information about an altered global environment and climate system (Prudhomme et al. 2003). However, in most climate change impact studies, such as hydrological impacts of climate change, impact models are usually required to simulate sub-grid scale phenomenon and therefore, require input data (such as temperature) at similar sub-grid scale. The methods used to convert GCM outputs into local meteorological variables required for reliable hydrological modeling are usually referred to as “downscaling” techniques. Hydrologic variables, such as temperature, evaporation, etc., are significant parameters for climate change impact studies. A proper assessment of probable future temperature and their variability are to be made for various hydroclimatology scenarios.
More recently, downscaling has found wide application in hydroclimatology for scenario construction and simulation/prediction of (1) low-frequency rainfall events (Wilby 1998), (2) mean temperature (Benestad 2001), (3) potential evaporation rates (Weisse and Oestreicher 2001), (4) daily T max and T min (Wilby et al. 2002), (5) streamflows (Cannon and Whitfield 2002), (6) runoff (Arnell et al. 2003), (7) soil erosion and crop yield (Zhang et al. 2004), (8) mean, minimum, and maximum air temperature (Kettle and Thompson 2004), (9) precipitation (Tripathi et al. 2006), (10) daily T max and T min (Schoof and Pryor 2001), (11) streamflow (Ghosh and Mujumdar 2008), (12) T max and T min (Anandhi et al. 2009), and (13) precipitation (Vimont et al. 2009).
Downscaling models make use of a strong observed empirical relationship between one or several large-scale predictors and a variable of interest at regional scale, the predictand. The relationships between these scales can be determined by a number of methods including regression (Kilsby et al. 1998), partial least squares (PLS) regression (Bergant and Kajfezˇ-Bogataj 2005), canonical correlation analysis (Heyen et al. 1996; Xoplaki et al. 2000), K-nearest neighbor (Gangopadhyay et al. 2005), and artificial neural networks (Hewitson and Crane 1994; Gardner and Dorling 1998; Cannon and Lord 2000; Schoof and Pryor 2001; Goyal and Ojha 2010a; Ojha et al. 2010). In the literature, authors have not found application of PLS regression technique for simultaneous downscaling of maximum and minimum temperatures as well as evaporation specifically for Indian region.
In this paper, we present a downscaling methodology based on PLS projection to latent structures regression technique to study climate change impact over Pichola lake basin in an arid region. The objectives of this study include: (1) predictor selection, based on variable Importance in the Projection (VIP) score; (2) downscaling of mean monthly maximum temperature (T max), minimum temperature (T min), and pan evaporation using PLS regression approach; (3) an application of simple multiplicative shift to correct the bias of mean monthly GCM-simulated variables, and (4) comparing results with neural network approach from simulations of Canadian Coupled Global Climate Model (CGCM3) for latest Intergovernmental Panel on Climate Change (IPCC) scenarios. The scenarios which are studied in this paper are relevant to IPCCs fourth assessment report which was released in 2007.
The remainder of this paper is structured as follows: section 2 provides a description of the study region and reasons for its selection. Section 3 provides details of various data used in the study. Section 4 describes briefly the PLS regression and the reasons for selection of the predictor variables for downscaling. Section 5 explains the proposed methodology for development of the PLS regression downscaling models for downscaling T max, T min, and pan evaporation to the lake basin and introduction of multiplicative shift for bias correction. Section 6 presents the results and discussion. Finally, section 7 provides the conclusions drawn from the study.
2 Study region
The area of the this study is the Pichola lake catchment in Rajasthan state in India that is situated from 72.5° to 77.5° E and 22.5° to 27.5° N. The Pichola lake basin, located in Udaipur district, Rajasthan is one of the major sources for water supply for this arid region. During the past several decades, the streamflow regime in the catchment has changed considerably, which resulted in water scarcity, low agriculture yield and degradation of the ecosystem in the study area. Regions with arid and semi-arid climates could be sensitive even to insignificant changes in climatic characteristics (Linz et al. 1990). Temperature affects the evapotranspiration (Jessie et al. 1996), evaporation, and desertification processes and is also considered as an indicator of environmental degradation and climate change. Understanding the relationships among the hydrologic regime, climate factors, and anthropogenic effects is important for the sustainable management of water resources in the entire catchment; hence, this study area was chosen because of the aforementioned reasons.
The mean monthly T max in the catchment varies from 19°C to 39.5°C and mean annual T max is 30.6°C. The mean monthly T min ranges from 3.4°C to 29.8°C based on decadal (1990–2000) observed value. The observed mean monthly T max and T min as well as pan evaporation have been shown in Fig. 1a, b for various months of year 2000, respectively. The location map of the study region is shown in Fig. 2.
3 Data extraction
The monthly mean atmospheric variables were derived from the National Center for Environmental Prediction (NCEP/NCAR; hereafter called NCEP) reanalysis data set (Kalnay et al. 1996) for the period of January 1948 to December 2000. The data have a horizontal resolution of 2.5° latitude × 2.5° longitude and 17 constant pressure levels in the vertical. The atmospheric variables are extracted for nine grid points whose latitude ranges from 22.5° to 27.5° N, and longitude ranges from 72.5° to 77.5° E at a spatial resolution of 2.5°. The meteorological data, i.e., T max and T min as well as pan evaporation are used at monthly time scale from records available for Pichola Lake which is located in Udaipur at 24°34′ N latitude and 73°40′ E longitude. The data is available for the period January 1990 to December 2000 (Khobragade 2009). The Canadian Center for Climate Modeling and Analysis (CCCma) (http://www.cccma.bc.ec.gc.ca) provides GCM data for a number of surface and atmospheric variables for the CGCM3 T47 version which has a horizontal resolution of roughly 3.75° latitude × 3.75° longitude and a vertical resolution of 31 levels. CGCM3 is the third version of the CCCMA Coupled Global Climate Model which makes use of a significantly updated atmospheric component AGCM3 and uses the same ocean component as in CGCM2. The data comprise of present-day (20C3M) and future simulations forced by four emission scenarios, namely A1B, A2, B1, and COMMIT.
The nine grid points surrounding the study region are selected as the spatial domain of the predictors to adequately cover the various circulation domains of the predictors considered in this study. The GCM data is re-gridded to a common 2.5° using inverse square interpolation technique (Willmott et al. 1985).The utility of this interpolation algorithm was examined in previous downscaling studies (Shannon and Hewitson 1996; Crane and Hewitson 1998; Tripathi et al. 2006; Ghosh and Mujumdar 2008; Goyal and Ojha 2010b, c). The development of downscaling models for each of the predictand variables T max and T min as well as pan evaporation begins with the selection of potential predictors, followed by the application of PLS regression on downscaling model. The developed model is then used to obtain projections of T max and T min as well as pan evaporation from simulations of CGCM3.
4 PLS regression and selection of predictors
4.1 PLS regression
PLS regression is used to describe the relationship between multiple response variables and predictors through the latent variables. PLS regression can analyze data with strongly collinear, noisy, and numerous X-variables, and also simultaneously model several response variables, Y. In general, the PLS approach is particularly useful when one or a set of dependent variables (or time series) need to be predicted by a (very) large set of predictor variables (or time series) that are strongly cross-correlated (Abdi 2003). This is often the case in empirical downscaling of climate variables (Bergant and Kajfež-Bogataj 2005). For details of PLS regression, readers are referred to Manne (1987, Lindgren et al. (1993), Rannar et al. (1994), and Wold et al. 2001).
4.2 Different error norms
The different statistical parameters of each model are calculated during calibration to get the best statistical agreement between observed and simulated meteorological variables. For this purpose, various statistical performance measures, such as coefficient of correlation (CC), root mean square error (RMSE) and Nash–Sutcliffe Efficiency Index (Nash and Sutcliffe 1970) were used to measure the performance of various models.
4.3 Selections of predictors
The selection of appropriate predictors is one of the most important steps in a downscaling exercise for downscaling predictands. The predictors are chosen by the following criteria: (1) predictors are skillfully predicted by GCMs; (2) they should represent important physical processes in the context of the enhanced greenhouse effect; (3) they should not be strongly correlated to each other (Hewitson and Crane 1996; Hellström et al. 2001; Cavazos and Hewitson 2005; Goyal and Ojha 2010d, e). Various authors, such as, Hertig and Jacobeit (2008), Anandhi et al. (2009) have used large-scale atmospheric variables, viz., air temperature, geo-potential height, zonal (u) and meridional (v) wind velocities, as the predictors for downscaling GCM output to temperature over an area. For this study, we have used a total of nine possible predictor variables, namely, air temperature (at 925,500 and 200 hPa pressure levels), geo-potential height (at 200 and 500 hPa pressure levels), zonal (u), and meridional (v) wind velocities (at 925 and 200 hPa pressure levels), as the predictors for downscaling GCM output to mean monthly temperature and pan evaporation over a catchment.
The VIP scores obtained by the PLS regression, has been paid an increasing attention as an importance measure of each explanatory variable or predictor (Chong and Jun 2005). The variable selection procedure under PLS is proposed with an application to downscaling technique for identifying influencing variables on understanding the impact of climate change. The VIP scores which are obtained by PLS regression, can be used to select most influential variables or predictors, X (Chong and Jun 2005). The VIP score can be estimated for jth X-variable by
where R d is defined as the mean of the squares of the correlation coefficients (R) between the variables and the component and p is number of predictors.
Usually the predictor variable whose VIP score is greater than 0.8 and above is considered as an important variable (Wold 1995; Eriksson et al. 2001)
It can be seen form Fig. 3a, b that seven predictor variables, namely, air temperature (925, 500, and 200 hPa); zonal wind (925 hPa); meridional wind (925 hPa); geo-potential height (500 and 200 hPa) have their VIP score greater than 0.8. Hence, these variables are used in the prediction model to obtain the projection of predictands. It is noted that different predictors control different local variables and mean temperature is most sensitive to surface and near surface atmospheric factors (Chu et al. 2010).
5 Downscaling of GCM models
PLS regression is used to downscale mean T max and T min as well as pan evaporation in this study. The data of potential predictors is first standardized. Standardization is widely used prior to statistical downscaling to reduce bias (if any) in the mean and the variance of GCM predictors with respect to that of NCEP-reanalysis data (Wilby et al. 2004). Standardization is done for a baseline period of 1948 to 2000 because it is of sufficient duration to establish a reliable climatology, yet not too long, nor too contemporary to include a strong global change signal (Wilby et al. 2004; Ghosh and Mujumdar 2008).
To develop downscaling models, the feature vectors (i.e., predictors) which are prepared from NCEP record, are partitioned into a training set and a validation set. Feature vectors in the training set are used for calibrating the model, and those in the validation set are used for validation. The 11-year mean monthly observed maximum and minimum temperatures as well as pan evaporation data series were broken up into a calibration period and a validation period. Table 1 summarizes the certain details of models. The various error criteria are used as an index to assess the performance of the model. Based on the latest IPCC scenario, models for mean monthly T max and T min as well as pan evaporation were evaluated based on the accuracy of the predictions for validation data set. The criteria such as Q²cum index, R²Xcum and R²Ycum index of PLS regression models were chosen in this study (Wold 1995; Eriksson et al. 2001; Wold et al. 2001).
Regression coefficients (Aij) for each predictor have been shown in Table 2 where i ranges from 1 to 7 indicating Ta 925, Ua 925, Va 925, Ta 500, Ta 200, Zg 200, and Zg 500, respectively, while j ranges from 1 to 9 representing location of points in grid, as shown in Fig. 2.
5.1 Correcting bias by a multiplicative shift
Many GCMs either overestimate or underestimate maximum and minimum temperature. The correction scheme brings the distributions close to the observed pattern. A simple multiplicative shift is used to correct the bias of the mean monthly GCM-simulated variable as follows:
where \( X_i^{\prime} \), X i refers to raw and corrected GCM-simulated variable, and \( \bar{X}_{\rm{GCM}} \) and \( \bar{X}_{\rm{obs}} \) are long term mean monthly variable from the GCM and the observations for given month (Amor and Hansen 2006).
6 Results and discussions
Seven predictor variables, namely, air temperature (925, 500, and 200 hPa); zonal wind (925 hPa); meridional wind (925 hPa); geo-potential height (500 and 200 hPa) at nine NCEP grid points with a dimensionality of 63, are used as the standardized data of potential predictors. These feature vectors are provided as input to the PLS regression downscaling model. Model quality indexes Q²cum index, R²Xcum and R²Ycum index have been shown in Table 3. It is clear that all three indices are highest for the first three components of the predictands. For predictand T max, Q²cum index, R²Xcum and R²Ycum index are 0.921, 0.931, and 0.929; respectively. For T min, Q²cum index, R²Xcum and R²Ycum index are 0.951, 0.928, and 0.956, respectively. Similarly, for predictand pan evaporation, Q²cum index, R²Xcum and R²Ycum index are obtained as 0.912, 0.892, and 0.941, respectively. Hence, model quality can be considered as good. PLS regression is performed on this dataset. Results of the different PLS regression models (viz. PLSM1, PLSM2, and PLSM3), as discussed in Table 1, are tabulated in Table 4. Neural network (NN) models have been developed for each predictand. A comprehensive search of neural network architecture is done by varying the number of nodes in hidden layer. The network is trained using back-propagation algorithm. Results of the different models of neural network technique (NNM1, NNM2, and NNM3 for T max , T min , and pan evaporation, respectively) were imported from previous study of Goyal and Ojha (2009). The calibration and validation results are described next.
6.1 Calibration/training results
It can be observed from Table 4 that for predictand T max, CC, RMSE and N-S Index were 0.96 1.23, and 0.92, respectively, using PLS regression model PLSM1 while CC, RMSE and N-S Index were 0.99, 0.96, and 0.98, respectively using neural network model NNM1. For predictand T min, values of CC, RMSE, N-S Index and MAE were 0.98, 1.55, and 0.93, respectively, while for model NNM2, values of CC, RMSE, N-S Index and MAE were 0.98, 0.91, and 0.96, respectively. The coefficient of correlation and N-S Index for the PLSM3 model were 0.95 and 0.89, respectively, whereas the values of the coefficient of correlation and N-S Index for the model NNM3 were 0.94 and 0.90, respectively, from predictand pan evaporation.
6.2 Validation/testing results
For predictand T max, values of CC, RMSE, N-S Index were 0.94, 1.63, and 0.92, respectively for PLSM1 model while values of CC, RMSE, N-S Index were 0.96, 2.31, and 0.91, respectively, for NNM1 model. For predictand T min, the values of CC and RMSE were 0.96 and 2.26, respectively, for PLSM2 model while the values of CC and RMSE were 0.94 and 1.62, respectively, for NNM2 model. The value of N-S Index was same, i.e., 0.87 for both models. The coefficient of correlation and N-S Index for the PLSM3 model were 0.89 and 0.85, respectively whereas the values of the coefficient of correlation and N-S Index for the model NNM3 were 0.90 and 0.84, respectively, for predictand pan evaporation.
Thus multiplicative shift is used to correct the bias of GCM of models PLSM1, PLSM2 and PLSM3 corresponding to T max, T min, and pan evaporation, respectively. All the corrected models performed better than uncorrected in terms of various performance meausres, as shown in Table 5. It can be inferred that the performance of PLS regression models bias corrected (viz. PLSM1 (corrected), PLSM2 (corrected), and PLSM3 (corrected)) for predictands (T max, T min as well as pan evaporation) performed well and are competitive in downscaling predictands values with neural network models and the comparsion shows that PLS regression is a reasonable choice.
A comparison of mean monthly observed T max and T min as well as pan evaporation with T max and T min as well as pan evaporation simulated using PLS regression models PLSM1 (corrected), PLSM2 (corrected), and PLSM3 (corrected) have been shown from Figs. 4, 5, and 6, respectively, for calibration and validation period.
Once the downscaling models have been calibrated and validated, the next step is to use these models to downscale the control scenario simulated by the GCM. The GCM simulations are run through the calibrated and validated PLS regression models to obtain future simulations of predictand. The predictands (viz. T max and T min as well as pan evaporation) patterns are analyzed with box plots for 20-year time slices. The middle line of the box gives the median whereas the upper and lower edges give the 75 percentile and 25 percentile of the data set, respectively. The difference between the 75 percentile and 25 percentile is known as inter quartile range (IQR). The two bounds of a box plot outside the box denote the value at ×1.5 IQR lower than the third quartile or minimum value, whichever is high and ×1.5 higher than the third quartile or the maximum value whichever is less. Typical results of downscaled predictands (T max and T min) obtained from the predictors are presented in Figs. 7, 8, and 9. In part (i) of these figures, the T max and T min downscaled using NCEP and GCM datasets are compared with the observed T max and T min for the study region using box plots. The projected T max and T min as well as an evaporation for 2001–2020, 2021–2040, 2041–2060, 2061–2080, and 2081–2100, for the four scenarios A1B, A2, B1, and COMMIT are shown in (ii), (iii), (iv), and (v) of Figs. 7, 8, and 9, respectively. From the box plots of downscaled predictands (Figs. 7 and 8), it can be observed that T max and T min are projected to increase in future for A1B, A2, and B1 scenarios, whereas no trend is discerned with the COMMIT scenario by using predictors.
Furthermore, the Mann–Kendall test was employed for trend analysis in the present study (Mann 1945; Kendall 1975). This nonparametric test has been extensively used to test randomness against trend. The test was performed for all the scenarios based on GCM downscale predictands. A value of 0.05 was chosen as the local significance level. Based on this significance level, values larger than 1.96 or lower than −1.96, respectively, indicate a significant positive or negative trend (Mishra et al. 2009). The results of the Mann–Kendall test statistics based on the various scenarios for period 2001–2100 are shown in Tables 5 and 6.
Historically, T max was observed in the month of June while T min was observed in the month of January in this region. Hence, these months were chosen as a part of this study for trend analysis. It is observed that there is no significant trend, either positive or negative, historically for both the predictands (T max and T min).
For predictand T max, it can be inferred from Table 5 that there is a significant rising trend during May month for SRESB1 and SRESA1B scenario. For predictand T min, it can be observed from Table 6 that there is a significant rising trend for SRESA2 and SRESB1 scenarios for January month for the period of 2001–2100.
Furthermore, it can be concluded that climate would be warmer in the future years. This will increase the vulnerability of the water resource system and further affect the safety of water in the lake catchment. Increase in temperature would result in increase in evapotranspiration which is a major cause of water depletion from riverine systems in arid and semi-arid climates (Dahm et al. 2002). While projected increase in temperatures may enhance the rate of evaporation in the study region since evaporation is proportional to the increase in the earth’s surface temperature (Anandhi et al. 2009). However, temperature is only one of the factors that determines the evaporative demand of the atmosphere, the others being vapor pressure deficit, wind speed and net radiation. The change in evaporative demand depends on how those factors change, as well as on the change in temperature (Rosenberg et al. 1989). Furthermore, increase in evaporation may lead to increase in precipitation since the evaporated water would eventually precipitate.
6.3 Comparison with previous downscaling studies
While this is the first study to use PLS regression approach for downsclaing of maximum and minimum temperature as well as pan evaporation prediction in Rajasthan, India, there have been a few studies using other methods in other parts of India. Hence, it is worthwhile to relate the performance of the models presented here with those presented in other studies that closely relate to this study.
In a recent study, Anandhi et al. (2009) developed statistical downscaling models using a support vector machine (SVM) approach for obtaining projections of monthly mean maximum and minimum temperatures (T max and T min) for a catchment of the Malaprabha reservoir in southern part of India. The analysis reveals that the SVM model is a feasible choice for downscaling the predictands. The resulting models produced similar results to those of this study. For example, the results of downscaling show that T max and T min are projected to increase in future for A1B, A2, and B1 scenarios, whereas no trend is discerned with the COMMIT. However, downscaling of evaporation has not been considered in this study. However, in the case of Anandhi et al. (2009), between the two predictands, T max was better simulated than T min, whereas in this work T min is better simulated than T max. Hence, it has demonstrated that PLS regression downsclaing method used in this study can accurately capture the trend for predictand T max and T min.
Since, no studies has been reported for downscaling the pan evaporation in India to the best of our knowledge. Hence, a comarison for pan evaporation has been made to a similar study carried out in semi-arid-Haihe River basin, China (Chu et al. 2010). Chu et al. 2010 developed the dowsncaling models for pan evaporation using statistical downsclaing method and results produced are similar to those of this study.
7 Conclusions
Statistical downscaling approaches are generally used to fill the gap between large-scale climate change and local scale response. In this study, PLS regression is applied to the lake catchment in India and we explored its applicability by downscaling mean maximum temperature, mean minimum temperature and pan evaporation simultaneously, which are significant for evaluating the impact of climate change on water resources management. Furthermore, we investigated their trend for future years which would pave the way for the study of hydro-climatological impacts on the lake catchment.
The selection of relevant predictors used for empirical model development plays a crucial role. VIP score obtained from PLS regression has been used for selection of important variables.GCM bias correction procedure improved the overall predictability of predictands. The results of downscaling models using PLS regression show that T max and T min are projected to increase in future for A1B, A2, and B1 scenarios, whereas no trend is discerned with the COMMIT scenario. Analysis for months (June for T max while January for T min) with historical T max and T min values reveals that no significant increasing or decreasing trend is found in the observed data at the significance level of 5%. At the significance level of 5%, it is observed that there is an increasing trend for T max for months of June for various scenarios while there is likely an increasing trend of minimum temperature for all the scenarios for months of January of the year in future. For pan evaporation, it can be concluded that trend is not obvious for future years since the factors working on pan evaporation are complicated.
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Appendix
Appendix
Abbreviations used in text
CCCma: Canadian Center for Climate Modeling and Analysis
CGCM: Canadian Coupled Global Climate Model
CGCM3: Third-generation Canadian Global Climate Model
GCM: Global Climate Model
IPCC: Intergovernmental panel on climate change
NCAR: National Center for Atmospheric Research, USA
RMSE: Root mean square error
SRES: Special report of emission scenarios
Ta 925: Air temperature at 925 hPa
Ua 925: Zonal wind at 925 hPa
Va 925: Meridional wind at 925 hPa
Ta 950: Air temperature at 500 hPa
Va 500: Meridional wind at 500 hPa
Zg 500: geo-potential height at 500 hPa
Ta 200: Air temperature at 200 hPa
Ua 200: Zonal wind at 200 hPa
Va 200: Meridional wind at 200 hPa
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Goyal, M.K., Ojha, C.S.P. PLS regression-based pan evaporation and minimum–maximum temperature projections for an arid lake basin in India. Theor Appl Climatol 105, 403–415 (2011). https://doi.org/10.1007/s00704-011-0406-z
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DOI: https://doi.org/10.1007/s00704-011-0406-z