Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning

Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning

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Spatial predictions of soil macro and micro-nutrient content across Sub-Saharan Africa at 250 m spatial resolution and for 0–30 cm depth interval are presented. Predictions were produced for 15 target nutrients: organic carbon (C) and total (organic) nitrogen (N), total phosphorus (P), and extractable—phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), sulfur (S), sodium (Na), iron (Fe), manganese (Mn), zinc (Zn), copper (Cu), aluminum (Al) and boron (B). Model training was performed using soil samples from ca. 59,000 locations (a compilation of soil samples from the AfSIS, EthioSIS, One Acre Fund, VitalSigns and legacy soil data) and an extensive stack of remote sensing covariates in addition to landform, lithologic and land cover maps. An ensemble model was then created for each nutrient from two machine learning algorithms—random forest and gradient boosting, as implemented in R packages ranger and xgboost—and then used to generate predictions in a fully-optimized computing system. Cross-validation revealed that apart from S, P and B, significant models can be produced for most targeted nutrients (R-square between 40–85%). Further comparison with OFRA field trial database shows that soil nutrients are indeed critical for agricultural development, with Mn, Zn, Al, B and Na, appearing as the most important nutrients for predicting crop yield. A limiting factor for mapping nutrients using the existing point data in Africa appears to be (1) the high spatial clustering of sampling locations, and (2) missing more detailed parent material/geological maps. Logical steps towards improving prediction accuracies include: further collection of input (training) point samples, further harmonization of measurement methods, addition of more detailed covariates specific to Africa, and implementation of a full spatio-temporal statistical modeling framework.

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Main Authors: Hengl, Tomislav, Leenaars, Johan G.B., Shepherd, Keith D., Walsh, Markus G., Heuvelink, Gerard B.M., Mamo, Tekalign, Tilahun, Helina, Berkhout, Ezra, Cooper, Matthew, Fegraus, Eric, Wheeler, Ichsani, Kwabena, Nketia A.
Format: Article/Letter to editor biblioteca
Language:English
Subjects:Africa, Machine learning, Macro-nutrients, Micro-nutrients, Random forest, Soil nutrient map, Spatial prediction,
Online Access:https://research.wur.nl/en/publications/soil-nutrient-maps-of-sub-saharan-africa-assessment-of-soil-nutri
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spelling dig-wur-nl-wurpubs-5247652024-10-02 Hengl, Tomislav Leenaars, Johan G.B. Shepherd, Keith D. Walsh, Markus G. Heuvelink, Gerard B.M. Mamo, Tekalign Tilahun, Helina Berkhout, Ezra Cooper, Matthew Fegraus, Eric Wheeler, Ichsani Kwabena, Nketia A. Article/Letter to editor Nutrient Cycling in Agroecosystems 109 (2017) 1 ISSN: 1385-1314 Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning 2017 Spatial predictions of soil macro and micro-nutrient content across Sub-Saharan Africa at 250 m spatial resolution and for 0–30 cm depth interval are presented. Predictions were produced for 15 target nutrients: organic carbon (C) and total (organic) nitrogen (N), total phosphorus (P), and extractable—phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), sulfur (S), sodium (Na), iron (Fe), manganese (Mn), zinc (Zn), copper (Cu), aluminum (Al) and boron (B). Model training was performed using soil samples from ca. 59,000 locations (a compilation of soil samples from the AfSIS, EthioSIS, One Acre Fund, VitalSigns and legacy soil data) and an extensive stack of remote sensing covariates in addition to landform, lithologic and land cover maps. An ensemble model was then created for each nutrient from two machine learning algorithms—random forest and gradient boosting, as implemented in R packages ranger and xgboost—and then used to generate predictions in a fully-optimized computing system. Cross-validation revealed that apart from S, P and B, significant models can be produced for most targeted nutrients (R-square between 40–85%). Further comparison with OFRA field trial database shows that soil nutrients are indeed critical for agricultural development, with Mn, Zn, Al, B and Na, appearing as the most important nutrients for predicting crop yield. A limiting factor for mapping nutrients using the existing point data in Africa appears to be (1) the high spatial clustering of sampling locations, and (2) missing more detailed parent material/geological maps. Logical steps towards improving prediction accuracies include: further collection of input (training) point samples, further harmonization of measurement methods, addition of more detailed covariates specific to Africa, and implementation of a full spatio-temporal statistical modeling framework. en application/pdf https://research.wur.nl/en/publications/soil-nutrient-maps-of-sub-saharan-africa-assessment-of-soil-nutri 10.1007/s10705-017-9870-x https://edepot.wur.nl/421230 Africa Machine learning Macro-nutrients Micro-nutrients Random forest Soil nutrient map Spatial prediction https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic Africa
Machine learning
Macro-nutrients
Micro-nutrients
Random forest
Soil nutrient map
Spatial prediction
Africa
Machine learning
Macro-nutrients
Micro-nutrients
Random forest
Soil nutrient map
Spatial prediction
spellingShingle Africa
Machine learning
Macro-nutrients
Micro-nutrients
Random forest
Soil nutrient map
Spatial prediction
Africa
Machine learning
Macro-nutrients
Micro-nutrients
Random forest
Soil nutrient map
Spatial prediction
Hengl, Tomislav
Leenaars, Johan G.B.
Shepherd, Keith D.
Walsh, Markus G.
Heuvelink, Gerard B.M.
Mamo, Tekalign
Tilahun, Helina
Berkhout, Ezra
Cooper, Matthew
Fegraus, Eric
Wheeler, Ichsani
Kwabena, Nketia A.
Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
description Spatial predictions of soil macro and micro-nutrient content across Sub-Saharan Africa at 250 m spatial resolution and for 0–30 cm depth interval are presented. Predictions were produced for 15 target nutrients: organic carbon (C) and total (organic) nitrogen (N), total phosphorus (P), and extractable—phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), sulfur (S), sodium (Na), iron (Fe), manganese (Mn), zinc (Zn), copper (Cu), aluminum (Al) and boron (B). Model training was performed using soil samples from ca. 59,000 locations (a compilation of soil samples from the AfSIS, EthioSIS, One Acre Fund, VitalSigns and legacy soil data) and an extensive stack of remote sensing covariates in addition to landform, lithologic and land cover maps. An ensemble model was then created for each nutrient from two machine learning algorithms—random forest and gradient boosting, as implemented in R packages ranger and xgboost—and then used to generate predictions in a fully-optimized computing system. Cross-validation revealed that apart from S, P and B, significant models can be produced for most targeted nutrients (R-square between 40–85%). Further comparison with OFRA field trial database shows that soil nutrients are indeed critical for agricultural development, with Mn, Zn, Al, B and Na, appearing as the most important nutrients for predicting crop yield. A limiting factor for mapping nutrients using the existing point data in Africa appears to be (1) the high spatial clustering of sampling locations, and (2) missing more detailed parent material/geological maps. Logical steps towards improving prediction accuracies include: further collection of input (training) point samples, further harmonization of measurement methods, addition of more detailed covariates specific to Africa, and implementation of a full spatio-temporal statistical modeling framework.
format Article/Letter to editor
topic_facet Africa
Machine learning
Macro-nutrients
Micro-nutrients
Random forest
Soil nutrient map
Spatial prediction
author Hengl, Tomislav
Leenaars, Johan G.B.
Shepherd, Keith D.
Walsh, Markus G.
Heuvelink, Gerard B.M.
Mamo, Tekalign
Tilahun, Helina
Berkhout, Ezra
Cooper, Matthew
Fegraus, Eric
Wheeler, Ichsani
Kwabena, Nketia A.
author_facet Hengl, Tomislav
Leenaars, Johan G.B.
Shepherd, Keith D.
Walsh, Markus G.
Heuvelink, Gerard B.M.
Mamo, Tekalign
Tilahun, Helina
Berkhout, Ezra
Cooper, Matthew
Fegraus, Eric
Wheeler, Ichsani
Kwabena, Nketia A.
author_sort Hengl, Tomislav
title Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
title_short Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
title_full Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
title_fullStr Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
title_full_unstemmed Soil nutrient maps of Sub-Saharan Africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
title_sort soil nutrient maps of sub-saharan africa : assessment of soil nutrient content at 250 m spatial resolution using machine learning
url https://research.wur.nl/en/publications/soil-nutrient-maps-of-sub-saharan-africa-assessment-of-soil-nutri
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