Improved selected soil properties predictions using MIR and pXRF sensor fusionOA
The timely and accurate assessment of soil nutrient information is essential for ensuring global food security and sustainable agricultural development.This study evaluated the individual and fusion performance of mid-infrared(MIR)and portable X-ray fluorescence(p XRF)spectroscopy for predicting selected soil properties.Four sensor fusion strategies were implemented:direct concatenation(DC),feature-level fusion using stability competitive adaptive reweighted sampling(s CARS)and least absolute shrinkage and selection operator(LASSO)algorithms(s CARS-C and LASSO-C),multiblock fusion via sequential orthogonal partial least squares(SO-PLS),and Granger-Ramanathan model averaging(GRA)method to enhance prediction accuracy for 13 soil properties.The findings revealed that single sensor models using either MIR or p XRF provided accurate estimations for soil organic matter(SOM),total nitrogen(TN),available phosphorus(AP),calcium(Ca),iron(Fe),manganese(Mn),and p H,but showed limitations for total potassium(TK),magnesium(Mg),copper(Cu),zinc(Zn),available potassium(AK),and total phosphorus(TP).The DC model significantly improved predictions for Mg(Rp^(2)=0.76,RMSEp=358.76 mg kg^(-1),RPDp=2.03)and TK(Rp^(2)=0.75,RMSEp=775.96 mg kg^(-1),RPDp=2.00).The LASSO-C model demonstrated superior prediction accuracy compared to the DC model for AP,AK,TP,Zn,Mn,and Cu,achieving optimal results for AP(Rp^(2)=0.89,RMSEp=21.37 mg kg^(-1),RPDp=3.01)and Zn(Rp^(2)=0.80,RMSEp=9.88 mg kg^(-1),RPDp=2.32).This enhancement is attributed to LASSO''s effective selection of feature information from the complete MIR and p XRF spectra.The GRA models achieved the highest prediction accuracy for TP,p H,AK,and Cu,with Rp^(2)values of 0.80,0.82,0.82,and 0.65,RMSEp values of 129.21 mg kg^(-1),0.13,48.38 mg kg^(-1),and 3.87 mg kg^(-1),and RPDp values of 2.23,2.34,2.37,and 1.67,respectively.For single-sensor applications,MIR spectra are recommended for predicting SOM,TN,and Ca(Rp^(2)≥0.88,RPDp≥2.87),while p XRF is more cost-effective for measuring Ca,Fe,and Mn(Rp^(2)≥0.80,RPDp≥2.22).This research demonstrates the effectiveness of MIR and p XRF sensor fusion in enhancing soil nutrient assessment accuracy,particularly for available nutrients and micronutrients.
Junwei Wang;Qi Zou;Huimin Yuan
College of Resources and Environmental Sciences/National Academy of Agriculture Green Development/Key Laboratory of Plant–Soil Interactions,Ministry of Education/China Agricultural University,Beijing 100193,China National Observation and Research Station of Agriculture Green Development,Quzhou 057250,ChinaCollege of Resources and Environmental Sciences/National Academy of Agriculture Green Development/Key Laboratory of Plant–Soil Interactions,Ministry of Education/China Agricultural University,Beijing 100193,China National Observation and Research Station of Agriculture Green Development,Quzhou 057250,ChinaCollege of Resources and Environmental Sciences/National Academy of Agriculture Green Development/Key Laboratory of Plant–Soil Interactions,Ministry of Education/China Agricultural University,Beijing 100193,China National Observation and Research Station of Agriculture Green Development,Quzhou 057250,China
农业科技
soil available nutrientsmicronutrientsmulti-block fusionfeature-level fusionmodel averaging
《Journal of Integrative Agriculture》 2026 (4)
P.1687-1699,13
supported by the National Key Research and Development Program of China(2023YFD1900104)。
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