2022
DOI: 10.1002/saj2.20472
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Compositional nutrient diagnosis and associated yield predictions in maize: A case study in the northern Guinea savanna of Nigeria

Abstract: Developing optimal strategies for nutrient management of soils and crops at a larger scale requires an understanding of nutrient limitations and imbalances. The availability of extensive data (n = 1,781) from 2‐yr nutrient omission trials in the most suitable agroecological zone for maize (Zea mays L.) in Nigeria (i.e., the northern Guinea savanna) provides an opportunity to assess nutrient limitations and imbalances using the concept of multi‐ratio compositional nutrient diagnosis (CND). We also compared and … Show more

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Cited by 3 publications
(1 citation statement)
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“…Machine learning models can effectively avoid this evaluation uncertainty caused by empirical knowledge and subjective judgement, and by learning from soil data, assessment models can be built more quickly and accurately. Zhou et al [14] used a combination of optical and radar remote sensing data to apply the SVM algorithm to build a Soil organic C (SOC) prediction model; Zou et al [15] collected historical soil data from southern China and combined multivariate linear model (MLM) and mixed effects regression model (MEM) for soil productivity assessment; Shehu et al [16] obtained 1781 sets of maize farmland data comparison in Northern Nigeria using linear regression models, as well as random forest machine learning to predict maize yields based on nutrient concentrations in spike leaves; Pan Y et al [17] provided an estimate of land productivity in the conterminous United States of America (CONUS) through machine learning algorithms using a data-driven approach to incorporate relationships from the data into the land productivity evaluation. However, challenges remain in terms of applicability and interpretability of machine learning models [18], including the requirement of datasets (e.g., combining large remote sensing datasets and larger historical datasets) and due to the black box nature of machine learning resulting in little insight into agricultural management.…”
Section: Introductionmentioning
confidence: 99%
“…Machine learning models can effectively avoid this evaluation uncertainty caused by empirical knowledge and subjective judgement, and by learning from soil data, assessment models can be built more quickly and accurately. Zhou et al [14] used a combination of optical and radar remote sensing data to apply the SVM algorithm to build a Soil organic C (SOC) prediction model; Zou et al [15] collected historical soil data from southern China and combined multivariate linear model (MLM) and mixed effects regression model (MEM) for soil productivity assessment; Shehu et al [16] obtained 1781 sets of maize farmland data comparison in Northern Nigeria using linear regression models, as well as random forest machine learning to predict maize yields based on nutrient concentrations in spike leaves; Pan Y et al [17] provided an estimate of land productivity in the conterminous United States of America (CONUS) through machine learning algorithms using a data-driven approach to incorporate relationships from the data into the land productivity evaluation. However, challenges remain in terms of applicability and interpretability of machine learning models [18], including the requirement of datasets (e.g., combining large remote sensing datasets and larger historical datasets) and due to the black box nature of machine learning resulting in little insight into agricultural management.…”
Section: Introductionmentioning
confidence: 99%