Abstract
Accurately monitoring heavy metal stress in crops is vital for food security and agricultural production. The assimilation of remote sensing images into the World Food Studies (WOFOST) model provides an efficient way to solve this problem. In this study, we aimed at investigating the key periods of the assimilation framework for continuous monitoring of heavy metal stress in rice. The Harris algorithm was used for the leaf area index (LAI) curves to select the key period for an optimized assimilation. To obtain accurate LAI values, the measured dry weight of rice roots (WRT), which have been proven to be the most stress-sensitive indicator of heavy metal stress, were incorporated into the improved WOFOST model. Finally, the key periods, which contain four dominant time points, were used to select remote sensing images for the RS-WOFOST model for continuous monitoring of heavy metal stress. Compared with the key period which contains all the available remote sensing images, the results showed that the optimal key period can significantly improve the time efficiency of the assimilation framework by shortening the model operation time by more than 50%, while maintaining its accuracy. This result is highly significant when monitoring heavy metals in rice on a large-scale. Furthermore, it can also offer a reference for the timing of field measurements in monitoring heavy metal stress in rice.
Highlights
Along with the rapid development of industrialization and urbanization, soil contamination by heavy metals in China continues to worsen
The measured weight of roots (WRT) was chosen as a state variable and used to modify the World Food Studies (WOFOST) model to simulate the continuous leaf area index (LAI) under heavy metal stress
The objective of this study was to select the key periods for the RS-WOFOST assimilation framework
Summary
Along with the rapid development of industrialization and urbanization, soil contamination by heavy metals in China continues to worsen. It is extremely important to control heavy metal pollution in agricultural soil and monitor agricultural eco-environments. Remote sensing plays an important role in monitoring heavy metal contamination. Numerous previous studies have investigated the relationship between spectral features (e.g., red edge position, spectral vegetation indices) and heavy metal concentrations or the physical characteristics of plants (e.g., leaf area index, yield, chlorophyll content) [6,7,8,9,10,11,12]. Many researchers have found that roots respond to heavy metal toxicity earlier and more strongly than the parts of the plant that are above ground [13,14,15,16,17]. The dry weight of roots (WRT) is a representative indicator for monitoring heavy metal stress; the WRT is Sensors 2018, 18, 1230; doi:10.3390/s18041230 www.mdpi.com/journal/sensors.
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