Abstract
Crop yield modeling at the regional level is one of the most important methods to ensure the profitability of the agro-industrial economy and the solving of the food security problem. Due to a lack of information about crop distribution over large agricultural areas, as well as the crop separation problem (based on remote sensing data) caused by the similarity of phenological cycles, a question arises regarding the relevance of using data obtained from the arable land mask of the region to predict the yield of individual crops. This study aimed to develop a regression model for soybean crop yield monitoring in municipalities and was conducted in the Khabarovsk Territory, located in the Russian Far East. Moderate Resolution Imaging Spectroradiometer (MODIS) data, an arable land mask, the meteorological characteristics obtained using the VEGA-Science web service, and crop yield data for 2010–2019 were used. The structure of crop distribution in the Khabarovsk District was reproduced in experimental fields, and Normalized Difference Vegetation Index (NDVI) seasonal variation approximating functions were constructed (both for total district sown area and different crops). It was found that the approximating function graph for the experimental fields corresponds to a similar graph for arable land. The maximum NDVI forecast error on the 30th week in 2019 using the approximation parameters according to 2014–2018 did not exceed 0.5%. The root-mean-square error (RMSE) was 0.054. The maximum value of the NDVI, as well as the indicators characterizing the temperature regime, soil moisture, and photosynthetically active radiation in the region during the period from the 1st to the 30th calendar weeks of the year, were previously considered as parameters of the regression model for predicting soybean yield. As a result of the experiments, the NDVI and the duration of the growing season were included in the regression model as independent variables. According to 2010–2018, the mean absolute percentage error (MAPE) of the regression model was 6.2%, and the soybean yield prediction absolute percentage error (APE) for 2019 was 6.3%, while RMSE was 0.13 t/ha. This approach was evaluated with a leave-one-year-out cross-validation procedure. When the calculated maximum NDVI value was used in the regression equation for early forecasting, MAPE in the 28th–30th weeks was less than 10%.
Highlights
Soybean is one of the main crops in the global agro-industrial complex [1]
We studied the possibility of predicting the maximum Normalized Difference Vegetation Index (NDVI) value, starting from the 22nd calendar week
An analysis of the results showed that the predicted values for most of the observed years are within the confidence interval (γ = 0.95) for the actual soybean yield (Figure 9)
Summary
Soybean is one of the main crops in the global agro-industrial complex [1]. Worldwide, soybean production ranks fourth among all grain and leguminous crops (after rice, wheat, and corn) (http: //fao.org/faostat), while the gross yield of the crop has increased by more than 50% in the 10 years from 2008 to 2018—that is, from 220 million to 340 million tons (http://www.indexbox.ru). That is why soybean is one of the main crops that allows to formulate a food security strategy at the government level in different countries, which is an urgent task in conditions of economic crisis [2] and, in particular, the expected consequences of COVID-19 [3]. The assessment of soybean yield at the field level was carried out in Reference [4,5]. These studies show that vegetation indexes (i.e., the Normalized Difference Vegetation Index (NDVI) and the Triangular Vegetation Index (TVI)) are related to cover crop biomass and, yield [5]. Widely used yield analysis methods applied to individual fields, taking into account soil and agrochemical characteristics, along with remote sensing indicators, are not always applicable at the regional level [6]
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