Soil Dynamics and Crop Yield Modeling Using the MONICA Crop Simulation Model and Time Series Forecasting Methods

Crop simulation models are an important tool for assessing agroecosystem performance and the impact of agrotechnologies on soil cover condition. However, the high uncertainty and labor intensiveness of long-term weather forecasting limits the applicability of such models. A possible solution may be to use time series forecasting models (SARIMAX and Prophet) and artificial neural-network-based technologies (Neural Prophet). This work compares the applicability of these methods for modeling soil condition dynamics and agroecosystem performance using the MONICA simulation model for Voronic Chernozems in the Kursk region of Russia. The goal is to determine which weather indicators are most important for the yield forecast and to choose the most appropriate methods for forecasting weather scenarios for agricultural modeling. Crop rotation of soybean and sugar beet was simulated, with agricultural techniques and fertilizer usage considered as factors. We demonstrated the high sensitivity of aboveground biomass production and soil moisture dynamics to daily temperature fluctuations and precipitation during the vegetation period. The dynamics of the leaf area index and nitrate content showed less sensitivity to the daily fluctuations of temperature and precipitation. Among the proposed forecasting methods, both SARIMAX and the Neural Prophet algorithm demonstrated the ability to forecast weather to model the dynamics of crop and soil conditions with the highest degree of approximation to actual observations. For the dynamic of the crop yield of soybean, the SARIMAX model exhibited the most favorable coefficient of determination, R2, while for sugar beet, the Neural Prophet model achieved superior R2 levels of 0.99 and 0.98, respectively.

[1]  A. Govind,et al.  An improved deep learning procedure for statistical downscaling of climate data , 2023, Heliyon.

[2]  M. Boucher,et al.  Hybrid forecasting: blending climate predictions with AI models , 2023, Hydrology and Earth System Sciences.

[3]  R. Cichota,et al.  Simulating water and nitrogen runoff with APSIM , 2023, Soil and Tillage Research.

[4]  G. Hoogenboom,et al.  Silver lining to a climate crisis in multiple prospects for alleviating crop waterlogging under future climates , 2023, Nature Communications.

[5]  Xingjian Shi,et al.  Earthformer: Exploring Space-Time Transformers for Earth System Forecasting , 2022, NeurIPS.

[6]  M. Schmeits,et al.  Using explainable machine learning forecasts to discover sub-seasonal drivers of high summer temperatures in western and central Europe , 2022, Monthly Weather Review.

[7]  G. Rodrigues,et al.  Estimation of Daily Reference Evapotranspiration from NASA POWER Reanalysis Products in a Hot Summer Mediterranean Climate , 2021, Agronomy.

[8]  I. Oseledets,et al.  Optimal soil sampling design based on the maxvol algorithm , 2021, ArXiv.

[9]  M. G. Schultz,et al.  Can deep learning beat numerical weather prediction? , 2021, Philosophical Transactions of the Royal Society A.

[10]  Jonathan A. Weyn,et al.  Sub‐Seasonal Forecasting With a Large Ensemble of Deep‐Learning Weather Prediction Models , 2021, Journal of Advances in Modeling Earth Systems.

[11]  Prashant Singh Rana,et al.  Long short-term memory neural network-based multi-level model for smart irrigation , 2020, Modern Physics Letters B.

[12]  P. Craufurd,et al.  Science-based decision support for formulating crop fertilizer recommendations in sub-Saharan Africa , 2020, Agricultural systems.

[13]  James W. Jones,et al.  Towards a multiscale crop modelling framework for climate change adaptation assessment , 2020, Nature Plants.

[14]  Jong-Chul Ha,et al.  Seasonal forecasting of daily mean air temperatures using a coupled global climate model and machine learning algorithm for field-scale agricultural management , 2020 .

[15]  P. Sentelhas,et al.  NASA/POWER and DailyGridded weather datasets—how good they are for estimating maize yields in Brazil? , 2019, International Journal of Biometeorology.

[16]  E. Rezaei,et al.  Crop Models as Tools for Agroclimatology , 2018, Agronomy Monographs.

[17]  Benjamin Letham,et al.  Forecasting at Scale , 2018, PeerJ Prepr..

[18]  Diane Ahrens,et al.  Application of SARIMAX Model to Forecast Daily Sales in Food Retail Industry , 2016, Int. J. Oper. Res. Inf. Syst..

[19]  Veronika Eyring,et al.  Overview of the Coupled Model Intercomparison Project Phase 6 (CMIP6) experimental design and organization , 2015 .

[20]  Ralf Wieland,et al.  Analysing the parameter sensitivity of the agro-ecosystem model MONICA for different crops , 2015 .

[21]  Chris Murphy,et al.  APSIM - Evolution towards a new generation of agricultural systems simulation , 2014, Environ. Model. Softw..

[22]  Vladimir Badenko,et al.  AGROTOOL Software as an Intellectual Core of Decision Support Systems in Computer Aided Agriculture , 2014 .

[23]  James W. Jones,et al.  How do various maize crop models vary in their responses to climate change factors? , 2014, Global change biology.

[24]  K. Cassman,et al.  Impact of derived global weather data on simulated crop yields , 2013, Global change biology.

[25]  M. Trnka,et al.  Simulation of spring barley yield in different climatic zones of Northern and Central Europe: A comparison of nine crop models , 2012 .

[26]  Andrew Nelson,et al.  Modeling and mapping potential epidemics of rice diseases globally , 2012 .

[27]  Roberto Confalonieri,et al.  Combining a weather generator and a standard sensitivity analysis method to quantify the relevance of weather variables on agrometeorological models outputs , 2012, Theoretical and Applied Climatology.

[28]  W. Mirschel,et al.  The MONICA model: Testing predictability for crop growth, soil moisture and nitrogen dynamics , 2011 .

[29]  Gerrit Hoogenboom,et al.  Simulating water content, crop yield and nitrate-N loss under free and controlled tile drainage with subsurface irrigation using the DSSAT model , 2011 .

[30]  James W. Jones,et al.  Modeling organic carbon and carbon-mediated soil processes in DSSAT v4.5 , 2010, Oper. Res..

[31]  M. Semenov Simulation of extreme weather events by a stochastic weather generator , 2008 .

[32]  J. Soussana,et al.  Adapting agriculture to climate change , 2007, Proceedings of the National Academy of Sciences.

[33]  Søren Hansen,et al.  Daisy: an open soil-crop-atmosphere system model , 2000, Environ. Model. Softw..

[34]  S. Hochreiter,et al.  Long Short-Term Memory , 1997, Neural Computation.

[35]  Marjan Alirezaie,et al.  Metrics and Evaluations of Time Series Explanations: An Application in Affect Computing , 2022, IEEE Access.

[36]  Alex J. Cannon,et al.  Using ensemble-mean climate scenarios for future crop yield projections: a stochastic weather generator approach , 2021 .

[37]  R. Lal Food security in a changing climate , 2013 .

[38]  Xin-ping Chen,et al.  Evaluation of NASA Satellite‐ and Model‐Derived Weather Data for Simulation of Maize Yield Potential in China , 2010 .

[39]  Pavel Senin,et al.  Dynamic Time Warping Algorithm Review , 2008 .

[40]  H. Sinoquet,et al.  An overview of the crop model STICS , 2003 .

[41]  James W. Jones,et al.  The DSSAT cropping system model , 2003 .