Abstract
Mapping irrigated areas using remotely sensed imagery has been widely applied to support agricultural water management; however, accuracy is often compromised by the in-field heterogeneity of and interannual variability in crop conditions. This paper addresses these key issues. Two classification methods were employed to map irrigated fields using normalized difference vegetation index (NDVI) values derived from Landsat 7 and Landsat 8: a dynamic thresholding method (method one) and a random forest method (method two). To improve the representativeness of field-level NDVI aggregates, which are the key inputs in our methods, a Gaussian mixture model (GMM)-based filtering approach was adopted to remove noncrop pixels (e.g., trees and bare soils) and mixed pixels along the field boundary. To improve the temporal transferability of method one we dynamically determined the threshold value to account for the impact of interannual weather variability based on the dynamic range of NDVI values. In method two an innovative training sample pool was designed for the random forest modeling to enable automatic calibration for each season, which contributes to consistent performance across years. The irrigated field mapping was applied to a major irrigation district in Australia from 2011 to 2018, for summer and winter cropping seasons separately. The results showed that using GMM-based filtering can markedly improve field-level data quality and avoid up to 1/3 of omission errors for irrigated fields. Method two showed superior performance, exhibiting consistent and good accuracy (kappa > 0.9) for both seasons. The classified maps in wet winter seasons should be used with caution, because rainfall alone can largely meet plant water requirements, leaving the contribution of irrigation to the surface spectral signature weak. The approaches introduced are transferable to other areas, can support multiyear irrigated area mapping with high accuracy, and significantly reduced model development effort.
Highlights
Introduction published maps and institutional affilGlobally, irrigated agriculture plays an important role in supporting agricultural production; water availability in the irrigation sector is limited due to hydrological factors, competing demands and the impact of climate change [1,2]
We developed a set of normalized difference vegetation index (NDVI) metrics as model inputs for the random forest classification
This paper focuses on developing field-scale data processing methods and temporally transferable classification methods to support multiyear irrigated area mapping
Summary
Irrigated agriculture plays an important role in supporting agricultural production; water availability in the irrigation sector is limited due to hydrological factors, competing demands and the impact of climate change [1,2]. Good planning and management are of great importance to support sustainable development in irrigated agriculture and secure food supply. Monitoring the performance of irrigation is an important component of efficient irrigation management, which is assisted by accurate irrigated area mapping. An irrigated area map is a fundamental input to understand irrigation water demand, water allocation and efficiency. It is one of the critical inputs to hydrological modeling, water budgeting and decision making [2,4,5]
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