Integrating APSIM model with machine learning to predict wheat yield spatial distribution

Kheir, Ahmed M. S.; Mkuhlani, Siyabusa; Mugo, Jane W.; Elnashar, Abdelrazek; Nangia, Vinay; Devare, Medha; Govind, Ajit

doi:10.1002/agj2.21470

Cited by 2 publications

(2 citation statements)

References 51 publications

(46 reference statements)

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“…Integrating both approaches can leverage their complementary strengths to enhance yield predictions and better understand the impacts of environmental variability and climate change on agriculture. Crop models and machine learning can be integrated [83] by employing crop model inputs and outputs as predictors in ML, together with other external variables that crop models cannot include, such as salinity, pests, diseases, and terrain, to predict yield at spatial explicit. Therefore, future directions could be done by coupling the developed approach (H 2 OautoML) with crop models to not only predict the current spatial yield, but also to explore future impacts, adaptation, and mitigation to climate change.…”

Section: Discussionmentioning

confidence: 99%

Developing automated machine learning approach for fast and robust crop yield prediction using a fusion of remote sensing, soil, and weather dataset

Kheir,

Govind,

Nangia

et al. 2024

Environ. Res. Commun.

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Estimating smallholder crop yields robustly and timely is crucial for improving agronomic practices, determining yield gaps, guiding investment, and policymaking to ensure food security. However, there is poor estimation of yield for most smallholders due to lack of technology, and field scale data, particularly in Egypt. Automated machine learning (AutoML) can be used to automate the machine learning workflow, including automatic training and optimization of multiple models within a user-specified time frame, but it has less attention so far. Here, we combined extensive field survey yield across wheat cultivated area in Egypt with diverse dataset of remote sensing, soil, and weather to predict field-level wheat yield using 22 ML models in AutoML. The models showed robust accuracies for yield predictions, recording Willmott degree of agreement, (d > 0.80) with higher accuracy when super learner (stacked ensemble) was used (R2 = 0.51, d = 0.82). The trained AutoML was deployed to predict yield using remote sensing (RS) vegetative indices (VIs), demonstrating a good correlation with actual yield (R2 = 0.7). This is very important since it is considered a low-cost tool and could be used to explore early yield predictions. Since climate change has negative impacts on agricultural production and food security with some uncertainties, AutoML was deployed to predict wheat yield under recent climate scenarios from the Coupled Model Intercomparison Project Phase 6 (CMIP6). These scenarios included single downscaled General Circulation Model (GCM) as CanESM5 and two shared socioeconomic pathways (SSPs) as SSP2-4.5and SSP5-8.5during the mid-term period (2050). The stacked ensemble model displayed declines in yield of 21 % and 5 % under SSP5-8.5 and SSP2-4.5 respectively during mid-century, with higher. The developed approach could be used as a rapid, accurate and low-cost method to predict yield for stakeholder farms all over the world where ground data is scarce.

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Section: Discussionmentioning

confidence: 99%

Developing automated machine learning approach for fast and robust crop yield prediction using a fusion of remote sensing, soil, and weather dataset

Kheir,

Govind,

Nangia

et al. 2024

Environ. Res. Commun.

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“…Furthermore, the effect of these materials on soil microbial activity and greenhouse gas emissions should be considered as a future research direction. On the other hand, including these resources into decision support tools such as crop models [48] will enable them to be used at scale in a cost-effective manner.…”

Section: Discussionmentioning

confidence: 99%

The Fusion Impact of Compost, Biochar, and Polymer on Sandy Soil Properties and Bean Productivity

Kheir,

Govind,

Zoghdan

et al. 2023

Agronomy

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Two of the most significant issues confronting arid and semi-arid countries are soil degradation and the need to reclaim sandy soils and improve their properties to enhance the agricultural area and ensure food security. Many attempts to improve sandy soil properties have been attempted using soil amendments, but further research is needed to explore the combined impact of cost-effective amendments. To that purpose, we investigated the impact of various soil amendments, including single and combination applications of synthetic Super Absorbent Polymer (SAP), compost, and biochar, on sandy soil physiochemical characteristics and bean (Vicia faba L.) production and quality throughout three growing seasons. In a randomized complete block design with three replicates per treatment, different treatments such as control (without application), lower dose of SAP (SAP1), higher dose of SAP (SAP2), biochar, compost, SAP1 plus biochar, SAP1 plus compost, SAP2 plus biochar, SAP2 plus compost, and biochar plus compost were used. The combined treatments, such as SAP2 plus biochar (T8), SAP2 plus compost (T9), and biochar plus compost (T10), improved soil physiochemical characteristics and crop production significantly. Application of T10 decreased soil bulk density by 15%, 17%, and 13% while increasing soil available water by 10%, 6%, and 3% over the first, second, and third growing seasons, respectively, compared to untreated soil (T1). The application of treatment (T9) surpassed other treatments in terms of yield, quality, and economic return, significantly increasing the seed yield by 24%, 26%, and 27% for the first, second, and third season compared with untreated soil. The higher rate of polymer combined with compost could be considered a cost-effective soil amendment to improve sandy soil productivity in arid and semi-arid regions.

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Integrating APSIM model with machine learning to predict wheat yield spatial distribution

Cited by 2 publications

References 51 publications

Developing automated machine learning approach for fast and robust crop yield prediction using a fusion of remote sensing, soil, and weather dataset

Developing automated machine learning approach for fast and robust crop yield prediction using a fusion of remote sensing, soil, and weather dataset

The Fusion Impact of Compost, Biochar, and Polymer on Sandy Soil Properties and Bean Productivity

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