Author:
Ma Chunyan,Liu Mingxing,Ding Fan,Li Changchun,Cui Yingqi,Chen Weinan,Wang Yilin
Abstract
AbstractCrop growth monitoring and yield estimate information can be obtained via appropriate metrics such as the leaf area index (LAI) and biomass. Such information is crucial for guiding agricultural production, ensuring food security, and maintaining sustainable agricultural development. Traditional methods of field measurement and monitoring typically have low efficiency and can only give limited untimely information. Alternatively, methods based on remote sensing technologies are fast, objective, and nondestructive. Indeed, remote sensing data assimilation and crop growth modeling represent an important trend in crop growth monitoring and yield estimation. In this study, we assimilate the leaf area index retrieved from Sentinel-2 remote sensing data for crop growth model of the simple algorithm for yield estimation (SAFY) in wheat. The SP-UCI optimization algorithm is used for fine-tuning for several SAFY parameters, namely the emergence date (D0), the effective light energy utilization rate (ELUE), and the senescence temperature threshold (STT) which is indicative of biological aging. These three sensitive parameters are set in order to attain the global minimum of an error function between the SAFY model predicted values and the LAI inversion values. This assimilation of remote sensing data into the crop growth model facilitates the LAI, biomass, and yield estimation. The estimation results were validated using data collected from 48 experimental plots during 2014 and 2015. For the 2014 data, the results showed coefficients of determination (R2) of the LAI, biomass and yield of 0.73, 0.83 and 0.49, respectively, with corresponding root-mean-squared error (RMSE) values of 0.72, 1.13 t/ha and 1.14 t/ha, respectively. For the 2015 data, the estimated R2 values of the LAI, biomass, and yield were 0.700, 0.85, and 0.61, respectively, with respective RMSE values of 0.83, 1.22 t/ha, and 1.39 t/ha, respectively. The estimated values were found to be in good agreement with the measured ones. This shows high applicability of the proposed data assimilation scheme in crop monitoring and yield estimation. As well, this scheme provides a reference for the assimilation of remote sensing data into crop growth models for regional crop monitoring and yield estimation.
Funder
Important Project of Science and Technology of the Henan Province
Scientific and Technological Innovation Team of Universities in Henan Province
the Natural Science Foundation of China
Publisher
Springer Science and Business Media LLC
Reference75 articles.
1. Ortiz, R., Sayre, K. D., Govaerts, B., Gupta, R. & Reynolds, M. Climate change: Can wheat beat the heat. Agric. Ecosyst. Environ. 126, 46–58 (2008).
2. Yu, Z. W. Introduction to Crop Cultivation. (China Agriculture Press, 2013).
3. Huang, J. F., Wang, Y., Wang, F. M. & Liu, Z. Red edge characteristics and leaf area index estimation model using hyperspectral data for rape. Trans. Chin. Soc. Agric. Eng. 22, 22–26 (2006).
4. Su, W., Zhan, J. G., Zhang, M. Z., Wu, D. & Zhang, R. Estimation method of crop leaf area index based on airborne LiDAR data. Trans. Chin. Soc. Agric. Mach. 47, 272–277 (2016).
5. Fieuzal, R. & Baup, F. Estimation of leaf area index and crop height of sunflowers using multi-temporal optical and SAR satellite data. Int. J. Remote Sens. 37, 1–30 (2016).