Your search found 2 records
1 Rose, C. W.; Yu, B.. 1998. Dynamic process modelling of hydrology and soil erosion. In de Vries, F. W. T. P.; Agus, F.; Kerr, J. (Eds.), Soil erosion at multiple scales: Principles and methods for assessing causes and impacts. Wallingford, UK; Bangkok, Thailand: CABI Publishing; IBSRAM. pp.269-286.
Soil conservation ; Hydrology ; Erosion ; Models ; Runoff ; Forecasting / Australia / Malaysia / Philippines / Thailand
(Location: IWMI-HQ Call no: 631.45 G000 DEV Record No: H027843)
2 Yu, B.; Shang, S. 2020. Estimating growing season evapotranspiration and transpiration of major crops over a large irrigation district from HJ-1A/1B data using a remote sensing-based dual source evapotranspiration model. Remote Sensing, 12(5):865. (Special issue: Remote Sensing in Agricultural Hydrology and Water Resources Modeling) [doi: https://doi.org/10.3390/rs12050865]
Crops ; Evapotranspiration ; Plant growth ; Irrigation water ; Remote sensing ; Satellite imagery ; Water balance ; Maize ; Sunflowers ; Models ; Normalized difference vegetation index / China / Inner Mongolia Autonomous Region / Hetao Irrigation District / Dengkou / Hangjinhouqi / Linhe / Wuyuan
(Location: IWMI HQ Call no: e-copy only Record No: H049725)
(6.10 MB) (6.10 MB)
Crop evapotranspiration (ET) is the largest water consumer of agriculture water in an irrigation district. Remote sensing (RS) technique has provided an effective way to map regional ET using various RS-based ET models over the past several decades. To map growing season ET of different crops and partition ET into evaporation (E) and transpiration (T) at regional scale, appropriate ET models should be further integrated with crop distribution maps in different years and crop growing seasons determined for each crop pixel. In this study, a hybrid dual-source scheme and trapezoid framework-based ET Model (HTEM) fed with HJ-1A/1B data was applied in Hetao Irrigation District (HID) of China from 2009 to 2015 to map crop growing season ET and T at 30 m resolution. The HTEM model with HJ-1A/1B data performed well in estimating ET in HID, and the finer spatial resolution of model input data can improve the estimation accuracy of ET. Combined with the annual crop planting map identified in previous study, and crop growing seasons determined from fitted Normalized Difference Vegetation Index (NDVI) curves for crop pixels, the spatial and temporal variations of growing season ET and T of major crops (maize and sunflower) were examined. The results indicate that ET and T of maize and sunflower reach their minimum values in the southwest HID with smaller crop planting density, and reach their maximum values in northwest HID with higher crop planting density. Over the study period with a decreasing trend of available irrigation water, ET and T in maize and sunflower growing seasons show decreasing trends, while ratios of T/ET show increasing trends, which implies that the adverse effect of decreased irrigation water diversion on crop growth is diminished due to the favorable portioning of E and T in cropland of HID. In addition, the calculation results of crop coefficients show that there is water stress to crop growth in the study area. The present results are helpful to better understand the spatial pattern of crop water consumption and water stress of different crops during crop growing season, and provide the basis for optimizing the spatial distribution of crop planting with less water consumption and more crop yield.
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