X. Cai, B.R Sharma, M.Matin, D Sharma and G. Sarath International workshop on “Tackling Water and Food Crisis in South Asia: Insights from the Indus-Gangetic Basin”, 2-3 December, 2009, New Delhi, India Use of Remote Sensing/ GIS and Census Data for Estimating Basin Level Water Productivity: Methodological Concepts
Basin focal project – Indo-Gangetic basin Basin fact sheet: Geographic Area: 2.25 million km 2 Population: 747 million Landscape: mountain to plain Annual precipitation: 100 – 4000 mm Cropland area: 1.14 million km 2 Cropping pattern: rice–wheat Water use by agri.: 91.4% Water sources: ground water and surface water A basin under extreme pressure… 2
Basin Water Productivity Assessment – What to Care? Magnitude – What’s the current status? Spatial Variation – Hot spots/bright spots? Causes – Why does WP vary (both high and low)? Irrigated vs. rainfed – What’s the option for sustainable development under water scarcity and food deficit conditions? Crop vs. livestock and fisheries – How is livestock and fisheries contributing to water use outputs? Scope for improvement – How much potential for, where? 3
Basin Water Productivity Assessment – A Remote Sensing Perspective Land productivity – The natural extent of “good” and “bad” areas; Water consumption – How much water is depleted by what finally in spite of various ground conditions and interventions, and where (which drop for which crop)? Cropped areas – Cropping patterns and the spatial distribution; Water resources – Rainfall monitoring(TRMM); Factors assessment – Spatial analysis on causes for variations. Scope for improvement – “Hot Spots” / ”Bright Spots” 4
Remote Sensing for WP Assessment in Large Basin Areas – The Challenges The dynamic relation of spectra reflectance to crop biophysical characteristics; The often seen gaps in remote sensing interpretations to statistical data; The uncertainties in land surface parameterization for surface energy balance modeling. 5
Water Productivity Assessment Using Remote Sensing – The Five Steps Crop Dominance Map Crop Productivity Maps Crop Consumptive Water Use Water Productivity and the Variations Causes for Variations and Scope for Improvement 6
Dataset 1.Census data: District wise crop area, yield and production, state wise livestock and fisheries production; 2.Satellite sensor data: Moderate Resolution Imaging Spectror- adiometer (MODIS) 250m 16 day Normalized Difference Vegetation Index (NDVI) mosaic of the basin, MODIS 1km 16 day Land Surface Temperature (LST) products: Nov 2005 – Oct 2006; 3.Weather data: Daily temperature, humidity, sea level pressure, precipitation, wind speed collected for 58 stations: 2005 – 2007; 4.Land Use Land Cover (LULC) maps: USGS GLC , IWMI IG basin LULC map 2005, IWMI GIAM 10km (1999) and 500m (2003); 5.Other data layers: Basin boundary, administrative boundaries, road, railway, and river networks, Digital Elevation Model(DEM) 6.Ground truth data: see continued… To use all kinds of available information for the purpose of large scale WP assessment. 7
Ground truth A ground truth mission was conducted in India from 8 th -17 th Oct, 2008 Across Indus and Gangetic river basin >2700km covered 175 samples –LULC –Cropping pattern –Agricultural productivity (cut and farmer survey) –Water use (rainfed, surface/GW) –Social-economic survey 8
Crop Dominance Map Synthesizing existing maps to a crop dominance map with GT data 500m, IWMI, 2003 (Base map) 500m, IWMI, km, USGS,
Crop Dominance Map Predominant crops: irrigated rice/rice-wheat rotation The predominant crops are mainly cultivated in a belt along the main streams of Ganges and Indus river. Crop coefficients of the basin as extracted from literature (values) and RS imagery (growth periods) 10
Crop productivity Step 1. District wise productivity map using census data IGB paddy rice yield map of 2005 Crop GVP map of India and Nepal for 2005 Kharif season The approach is illustrated for rice, wheat is also done in the same way 11
Crop productivity Step 2. Pixel wise rice productivity map interpolation using MODIS data paddy rice yield map of 2005 NDVI composition of 29 Aug – 5 Sept 2005 for rice area MODIS 250m NDVI at rice heading stage was used to interpolate yield from district average to pixel wise employing rice yield ~ NDVI linear relationship. 12
Actual ET estimation Step 1. Potential ET calculation ( as example) Daily data from 58 weather stations Steps: 1.Hargreaves equation for reference ET. 2.Kc approach for potential ET. Note: Kc (FAO56) was determined by maximum Kc values of major crop of the month potential ET map (2005 Sept 21) 13
Actual ET estimation Step 2. Actual ET calculation by Simplified Surface Energy Balance (SSEB) approach Seasonal actual ET map (2005 Jun 10 – Oct 15) potential ET map (2005 Sept 21) ET a – the actual Evapotranspiration, mm. ET f – the evaporative fraction, 0-1, unitless. ET 0 – Potential ET, mm. T x – the Land Surface Temperature (LST) of pixel x from thermal data. T H /T C – the LST of hottest/coldest pixels. SSEB ET fraction map (2005 Sept 21) MODIS LST 2005 Sept 21 14
Rice yield and ETa maps Huge variation in yield, indicating significant scope for improvement Yield (ton/ha) PakistanIndiaNepalBangladesh Yield ET ET is high where yield is high. However, ET might also be high where yield is not (so) high. Why? ETa (mm) 15
Wheat yield and ETa maps PakistanIndiaNepalBangladesh Yield ET Yield (ton/ha) ETa (mm) Huge variation in yield, indicating significant scope for improvement Wheat ET variation is more consistent with yield 16
Water productivity maps Rice (kg/m 3 ) AVGSDVMinMax Wheat (kg/m 3 ) AVGSDVMinMax Note: 1% of the points with extremely low and high values are sieved from the statistics 17
Thank you 18