Browsing by Author "Shetty, Amba."

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Asymmetric Relationship of Nino Indices with Rainfall Extremes over Western Ghats and Coastal Region of Karnataka
(National Institute of Technology Karnataka, Surathkal, 2020) C, Vinay D.; Shetty, Amba.
Climate variability and change has increased extreme rainfall events. There is an underreporting and limited analysis, which often have significant impact with extreme rainfall events at regional scale. The magnitude of variability of the rainfall extremes varies according to locations. Among subdivisions of Western Ghats of India maximum rainfall occurs over Coastal Karnataka. Examining the extreme events of rainfall provide an idea of the probable occurrence of severity conditions in future in the context of changing climate. Extreme rainfall indices to identify the variation of rainfall patterns such as the number of rainy days, total rainfall, daily intensity index, one and five-day maximum rainfall, dry spells and threshold intensity rainfall frequency indices were considered as per the norms suggested by Expert Team on Climate Change Detection (ETCCDI) of Intergovernmental Panel on Climate Change (IPCC). These rainfall extremes indices are analyzed using IMD gridded high resolution daily rainfall data for the period 1901-2013. Statistical trend analysis techniques namely Mann–Kendall test applied for extreme rainfall indices and Theil-Sen estimator perceive nature and magnitude of slope in rainfall indices. The trends show contrasting spatial variations of extreme rainfall indices in Coastal region (low land) and Western Ghats (high land) regions of Karnataka. The changes in daily rainfall events in the lowland region primarily indicate statistically significant (varies from 95% to 99.9% confidence level) positive trends in the annual total rainfall, 1-day, and 5-day maximum rainfall, frequency of very heavy rainfall, and heavy rainfall as well as medium rainfall events. The seasonal variation of rainfall exhibits mixed trend, however significantly rising trend is witnessed in the southern coastal plains and the adjacent Western Ghats region during the pre-monsoon. But, southern coastal plains show a decreasing trend in the monsoon period (JJAS). Furthermore, the overall annual rainfall strongly correlated with all the rainfall indices in both regions, especially with indices that represent heavy rainfall events which are responsible for the total increase of rainfall. The interannual variability of rainfall and its extreme events over study region is observed to be associated with ENSO cycle, whereas Nino indices are asymmetric over the study region. The trends in ETCCDI extreme rainfall indices analyzed as an issue of climate change and the possible teleconnection with the ENSO mode as a concern of natural climatic variability have been analyzed over the study region. Nevertheless, differences are foundii between the spatial extent of correlation coefficients and their magnitudes. Using most significant time lag between the extreme rainfall indices (dependent variable) and the November-January (ONDJ) seasonal average of Niño indices (independent variable). The best model with the highest coefficient of determination was identified by Step wise regression analysis. The teleconnection between the Niño indices (Niño 1+2, Niño 3, Niño 3.4 and Niño 4) and the rainfall extremes with 0-year and 1-year ahead are at different phases, regional response of rainfall extremes to these indices are dissimilar. This analysis provides insights into regional response of rainfall extremes to global climate indices over the study region. The large-scale phenomenon over the pacific ocean with rainfall over the study region provide a scientific basis for understanding and developing credibility in future regional climate. A significant lag correlation between the summer monsoon rainfall and Niño indices was revealed by the seasonal lead-lag correlation analysis, Niño 3(t-4) at 90% confidence level, remaining Niño 3.4(t-2), Niño 4(t-2), and Niño 4(t-3) at 95% confidence level shows a significant relationship at respective lag period from onset of summer monsoon rainfall. In order to investigate the combined lagged effects of the potential climate predictors for monsoon rainfall using multiple linear regression as a linear method compared to neural network as a nonlinear method have been employed to examine the predictability of the summer monsoon rainfall. The principal component analysis of predictors aids to represent in one-dimensional space using the eigen vector that corresponds to the covariance matrix’s largest eigen value. Whereas first principal component explains about 72% of the variance of the predictors. Thus, PC1 considered as predictor in regression equation and input layer in neural network models to avoid over fitting. The attained prediction on the basis of the overall performance of the prediction models, feed forward neural network model shows a better prediction compared to other models with a good correlation coefficient and RMSE of 0.53 and 1.6 for training case, and 0.72 and 1.63 for testing case, respectively. From the time series analysis for period 1951-2013 of standardized monsoon rainfall Index selected the positive episodes values having standardized value greater than +1 (excess) and similarly with negative episodes values with standardized values less than -1 (deficit). The mean anomalous SST values for the region Nino 3.4 for the season DJF (- 2) for positive episode is 0.1719oC and the negative episode is -0.5133oC. The two SST means are significantly different at confidence level of 87.15% through the Student’s t-test.iii In awaken of climate change, this study is a contribution in the on-going research of extreme events over mountainous terrain including disaster management study. The sequential daily rainfall extremes and other atmospheric parameters may be utilized for the now-casting of extreme rainfall events. Further the relationship between topography and other atmospheric parameters influence for rainfall extremes should be studied separately to get better insight. This research may also be useful for the modifications in rainfall extremes retrieval methods over the Western Ghats mountainous terrain.
Integrated Water Resource Modelling for Improved Agricultural Productivity in OMO-Gibe Basin Ethiopia
(National Institute of Technology Karnataka, Surathkal, 2021) Kebede, Mudesir Nesru.; Shetty, Amba.; Nagaraj, M. K.
The lack of data in many river basins hinders the effective management of water resources. This is true in many river basins of Ethiopia. In this study, remote sensing images and the hydrological model were used jointly to bridge the gap in understanding of the hydrological processes of a watershed with sparse measured data. Understanding of water balance components is imperative for proper policy and decision-making. Such assessments are not available in many river basin across the globe, specifically in the upper part of the Omo- Gibe basin (UOGB) Ethiopia. The objective of this study was; (i) to explore the possibility of assessing consumption and availability of water using freely available satellite data and secondary data, (ii) to test the efficiency of satellite-based actual evapotranspiration in the HBV hydrological model to render the catchment water balance using multi-variable calibration and (iii) to come up with a strategy to increase cereals production by 2030 using available water resources in the upper Omo-Gibe basin. The Surface Energy Balance System (SEBS) is used to estimate spatiotemporal variability of actual evapotranspiration of the basin, while the Hydrologiska Byran's Vettenbalansavdeling (HBV) rainfall-runoff hydrological model is used to simulate streamflow as well as actual evapotranspiration. A spatial average of rainfall was computed using the Thiessen polygon approach. Actual evapotranspiration (ETa) was estimated through the Surface Energy Balance System (SEBS). Temporal MODIS images were used to estimate the spatial distribution of actual evapotranspiration covering the crop cycle during the study year. Additionally, Priestly and Taylor's approach was used to estimate reference evapotranspiration (ET0). The result of estimated precipitation and ETa showed that the UOGB received 41,080Mm3 of precipitation for the given study period, while 24,135Mm3 become evapotranspired. The assessed outflow from the basin is 17.6% of the precipitation and demonstrated that water is a scarce resource in the UOGB. Conventional practice of calibration of any hydrological model in any river basin is performed using a single hydrological variable, namely streamflow. Spatially distributed hydrological modelling provides an opportunity to enhance the use of multi-variable iii calibration models. Five years (2000-2004), meteorological data, streamflow, and actual evapotranspiration (ETa) based on remote sensing were used for calibration and validation purposes. The performance of the HBV model and the efficiency of SEBS-ETa were evaluated using certain calibration criteria (objective function). The model is first calibrated using only streamflow data to test HBV model performance and then calibrated using a multi-variable (streamflow and ETa) dataset to evaluate the efficiency of SEBSETa. Both model setups were validated in a multi-variable evaluation using streamflow and ETa data. In the first case, the model performed well enough for streamflow and poor for ETa, while in the latter case, the performance efficiency of SEBS-ETa and streamflow data shows satisfactory to good. This implies that the performance of hydrological models is enhanced by employing multi-variable calibration. Maize crops production yield in the water-scarce UOGB, can be increased by increasing crop water productivity and improving agricultural management. Based on the CWP and ETa/ETp analysis, the seasonal average Abelti maize CWP is 0.3 Kg/m3. In addition, the ETa of rainfed maize over the main maize growth period is 520 mm per season. Crop production function analysis and its planting can be studied as a function of the amount of seeds, fertilizers, and water utilized to evaluate the crop yield in the study area for the rainfed maize area. A total of 30,287.17 ha of suitable pastoral land has been converted/expanded to a rainfed maize area in the three slope classes (namely fairly, suitable land sloping classes, the moderately suitable land sloping classes, and the average suitable sloping class)of the basin. The two strategies identified to meet the expected 2030 UOGB rainfed maize production target are assessed based on a one-fourth, two-fourth, and three-fourth increase in yield gaps. In the first strategy, the increase in yield gaps by onefourth, two-fourth, and three-fourth contributes 23.12%, 46.23 %, and 69.35% of the total targeted production in the current rainfed maize area of the basin in the same order. Whereas, in the second strategy, the increase in production for additional suitable land contributed 0.80, 0.39 and 0.68, 1.61, 0.79 and 1.36, and 2.41, 1.18, and 2.04% of the planned target production in the same order.