Abstract
Organic fertilizer is a key component of agricultural sustainability and significantly contributes to the improvement of soil fertility. The values of nutrients such as organic matter and nitrogen in organic fertilizers positively affect plant growth and cause environmental problems when used in large amounts. Hence the importance of implementing fast detection of nitrogen (N) and organic matter (OM). This paper examines the feasibility of a framework that combined a particle swarm optimization (PSO) and two multiple stacked generalizations to determine the amount of nitrogen and organic matter in organic-fertilizer using visible near-infrared spectroscopy (Vis-NIR). The first multiple stacked generalizations for classification coupled with PSO (FSGC-PSO) were for feature selection purposes, while the second stacked generalizations for regression (SSGR) improved the detection of nitrogen and organic matter. The computation of root means square error (RMSE) and the coefficient of determination for calibration and prediction set (R2) was used to gauge the different models. The obtained FSGC-PSO subset combined with SSGR achieved significantly better prediction results than conventional methods such as Ridge, support vector machine (SVM), and partial least square (PLS) for both nitrogen (R2p = 0.9989, root mean square error of prediction (RMSEP) = 0.031 and limit of detection (LOD) = 2.97) and organic matter (R2p = 0.9972, RMSEP = 0.051 and LOD = 2.97). Therefore, our settled approach can be implemented as a promising way to monitor and evaluate the amount of N and OM in organic fertilizer.
Highlights
Organic fertilizers are biodegradable and environmentally friendly, which makes better nutrient sources
This study proposed a novel framework that combined a particle swarm optimization (PSO) and two multiple-stacked generalizations to determine the amount of organic matter (OM) and nitrogen (N) in organic fertilizer
The first multiple-stacked generalizations coupled with PSO (FSGC-PSO) were used to select the best features, while the second multiple-stacked generalizations (SSGR) improved the detection of N and OM
Summary
Organic fertilizers (biofertilizers) are biodegradable and environmentally friendly, which makes better nutrient sources. The amount of nitrogen (N) and organic matter (OM) in biofertilizers may directly affect the physical and chemical properties of soil and play a positive role in crop development [1]. Many industrial or even homemade biofertilizers fail to meet nutritional requirements, posing environmental risks. A high level of nitrogen (N) can evaporate into the atmosphere and result in serious environmental issues such as ammonia (NH3) and ozone (O3), limiting our ability to breathe, limiting visibility, and affecting plant growth. Excessive use of organic matter (OM) can result in the release of chemicals that delay plant growth and may promote the development of some unwanted plants. Rapid, cost-effective, and reliable determination is needed to improve local agricultural production, sustainability, and environmental protection
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