A data-mining approach for developing site-specific fertilizer response functions across the wheat-growing environments in Ethiopia

IF 1.6 4区农林科学 Q1 Agricultural and Biological Sciences

Experimental Agriculture Pub Date : 2022-03-11 DOI:10.1017/S0014479722000047

W. Abera, L. Tamene, K. Tesfaye, Daniel Jiménez, Hugo Dorado, T. Erkossa, J. Kihara, J. S. Ahmed, T. Amede, J. Ramirez-Villegas

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引用次数: 5

Abstract

Summary The use of chemical fertilizers is among the main innovations brought by the 1960s Green Revolution. In Ethiopia, fertilizer application during the last four decades has led to significant yield gains, yet yield remains below its potential across much of the country. One of the main challenges responsible for low yield response to fertilizer application has been the use of ‘blanket’ recommendations, whereby no tailoring of fertilizer amount and frequency is done based on soil requirements. As a result, the amount of fertilizer applied ranges widely, and can be either sub- or supra-optimal. There is thus an increasing need for site-specific fertilizer recommendations which take into account site characteristics such as climate variables (temperature, rainfall, and solar radiation); soil factors (soil organic carbon, moisture, pH, texture, cation exchange capacity, and level of macro- and micronutrients); and topographic position indices. This article reports on a data-mining approach we developed on a large dataset of 6585 wheat (Triticum aestivum) field trials. The dataset includes detailed, site-specific biophysical variables to create nutrient response functions that can guide optimal site-specific fertilizer application. The approach used a machine-learning model (random forest) to capture the relationship between nutrients – nitrogen (N), phosphorous (P), potassium (K), and sulfur (S) – and wheat yield. The model explained about 83, 82, 47, and 69% of variances of yield for N, P, K, and S omission, respectively, with consistent performance across training and testing datasets. Expectedly, for N and P omission data, the most important explanatory variables are nutrient rate, followed by soil organic carbon and soil pH. For K and S, however, climatic variables played an important role alongside nutrient rates. The site-specific yield–fertilizer response curves derived from our model are highly variable from location to location, as they are affected by the climatic, soil, or topographic conditions of the site. Importantly, using principal component analysis, we showed that the shape of the fertilizer response curves is a result of the multiple environmental factors (including soil, topography, and climate) that are at play at a given site, rather than of a specific dominant one. The research output is expected to respond to the national policy demands for a sound method to identify the optimal fertilizer rate to increase economic returns of fertilizer investments and take fertilizer utilization research one step further.

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一种数据挖掘方法，用于在埃塞俄比亚的小麦生长环境中开发特定地点的肥料响应函数

摘要化肥的使用是20世纪60年代绿色革命带来的主要创新之一。在埃塞俄比亚，过去四十年的化肥施用带来了显著的产量增长，但该国大部分地区的产量仍低于其潜力。造成化肥施用产量低的主要挑战之一是使用“一揽子”建议，即不根据土壤需求调整肥料的用量和频率。因此，施肥量的范围很广，可以是次优或超优。因此，越来越需要针对特定地点的肥料建议，这些建议考虑到了气候变量（温度、降雨量和太阳辐射）等地点特征；土壤因素（土壤有机碳、水分、pH、质地、阳离子交换能力以及宏观和微量营养素水平）；以及地形位置指数。本文报道了我们在6585个小麦（Triticum aestivum）田间试验的大型数据集上开发的数据挖掘方法。该数据集包括详细的、特定地点的生物物理变量，以创建营养反应函数，从而指导特定地点的最佳肥料施用。该方法使用机器学习模型（随机森林）来捕捉营养素——氮（N）、磷（P）、钾（K）和硫（S）——与小麦产量之间的关系。该模型分别解释了N、P、K和S遗漏的产量方差的83%、82%、47%和69%，在训练和测试数据集中表现一致。不出所料，对于N和P的遗漏数据，最重要的解释变量是养分速率，其次是土壤有机碳和土壤pH。然而，对于K和S，气候变量与养分速率一起发挥着重要作用。根据我们的模型得出的特定地点产量-肥料响应曲线因地点而异，因为它们受到地点的气候、土壤或地形条件的影响。重要的是，使用主成分分析，我们表明肥料响应曲线的形状是在给定地点发挥作用的多种环境因素（包括土壤、地形和气候）的结果，而不是特定的主导因素。研究成果预计将响应国家政策的要求，即确定最佳施肥率的合理方法，以提高肥料投资的经济回报，并使肥料利用研究更进一步。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Experimental Agriculture 农林科学-农艺学

CiteScore

2.50

自引率

6.20%

发文量

审稿时长

24 months

期刊介绍： With a focus on the tropical and sub-tropical regions of the world, Experimental Agriculture publishes the results of original research on field, plantation and herbage crops grown for food or feed, or for industrial purposes, and on farming systems, including livestock and people. It reports experimental work designed to explain how crops respond to the environment in biological and physical terms, and on the social and economic issues that may influence the uptake of the results of research by policy makers and farmers, including the role of institutions and partnerships in delivering impact. The journal also publishes accounts and critical discussions of new quantitative and qualitative methods in agricultural and ecosystems research, and of contemporary issues arising in countries where agricultural production needs to develop rapidly. There is a regular book review section and occasional, often invited, reviews of research.