首页|期刊导航|农业工程学报|便携式农田土壤有机质含量多光谱检测装置设计与试验

便携式农田土壤有机质含量多光谱检测装置设计与试验OA

Portable multispectral detection device for soil organic matter content in farmland

中文摘要英文摘要

为实现农田环境下土壤有机质(soil organic matter,SOM)含量的便携式、快速无损检测,该研究开发了一种基于多光谱技术的 SOM含量检测装置.通过 4种特征波长提取算法结合变量重要性投影方法,同时考虑水分影响,确定了7个 SOM特征波长(420、530、600、630、855、900、1 345 nm)和 1个土壤含水率校正波长(1 450 nm).基于此设计了装置的软硬件系统,集成主控模块、光谱采集模块、电源管理模块和人机交互模块,利用窄带 LED和光电二极管实现多光谱数据的获取.利用开发的装置采集了土壤的多光谱数据,对比干燥土壤建模、整体建模、分层建模 3种建模策略的预测能力,结果表明分层建模预测效果最佳,利用偏最小二乘(partial least squares,PLS)算法进行含水率梯度分类,结合多层感知机(multilayer perceptron,MLP)算法进行 SOM含量估测,构建 PLS-MLP分层回归算法,模型决定系数为 0.84,均方根误差为 3.93 g/kg,相对分析误差为 2.50.将模型嵌入装置后进行测试,与实验室测定值的相关系数为 0.82,均方根误差为 5.27 g/kg,相对分析误差为 1.64,重复测试标准差小于 0.4 g/kg,单次检测耗时小于 9 s.该装置能快速、准确估测SOM含量,具有较好的应用潜力.

Soil organic matter(SOM)can enhance the soil structure and fertility in the nutrient cycling under carbon sequestration.However,conventional chemical analysis can suffer from some drawbacks,including the lengthy processing times,operational complexity,high costs,and the destruction of soil samples.It is often required for the rapid,and large-scale monitoring in modern precision agriculture.In this study,a portable device was developed for the accurate,rapid and non-destructive detection of SOM content in agricultural field environments using multispectral technology.The 237 soil samples were collected from Ningxia and Shaanxi Province in China.Visible-near infrared(Vis-NIR)spectral data was obtained for the reference values of the SOM content.Spectral preprocessing was implemented to remove the outliers.Four algorithms of the feature wavelength-namely moving window PLS(MWPLS),iterative random forests(iRF),variable dimension particle swarm optimization using combined moving window(VDPSO-CMW),and moving window smoothing on the ensemble of competitive adaptive reweighted sampling(MWS-ECARS)-were employed to conjunct with the variable importance in Projection(VIP).Seven characteristic wavelengths of the SOM were successfully identified:420,530,600,630,855,900,and 1 345 nm.Thereby the spectral dimensionality and complexity of the dataset were significantly reduced after optimization.Furthermore,a correction wavelength at 1 450 nm was also selected for the soil moisture adjustment,in order to avoid the interference of the soil moisture on the spectral signals.The hardware and software systems of the device were designed,according to the characteristic wavelengths and the ESP32 embedded platform.Four modules were integrated in the device,including a main control,a multispectral acquisition,a power management and a human-machine interaction.Multispectral data was acquired using narrow-band LED light sources.The characteristic wavelengths were integrated with the photodiodes.Subsequently,the device was also used to collect the soil multispectral data.The dry soil,global and stratified modelling were constructed using three machine learning algorithms-partial least squares(PLS),multilayer perceptron(MLP),and support vector machine(SVM).The results indicated that the stratified modelling was yielded the best performance.The independent SOM prediction models were established for each moisture gradient.The soil moisture content was firstly estimated during actual prediction.The moisture gradient was determined as the sub-model to predict the SOM content.Thereby the accurate SOM estimation was realized under the varying soil moisture conditions.A PLS-MLP stratified regression model was constructed to acquire multispectral data using the prototype device.The PLS algorithm was used for the moisture gradient classification,and then applied the MLP algorithm to estimate the SOM content.The better performance of the model was achieved in a coefficient of determination(R2)of 0.84,a root mean square error(RMSE)of 3.93 g/kg,and a relative prediction deviation(RPD)of 2.50.The model was embedded into the device for testing.The correlation coefficient between the estimated and laboratory-measured values reached 0.82,with an RMSE of 5.27 g/kg,an RPD of 1.64,a standard deviation for the repeated tests of less than 0.4 g/kg,and a single detection time under 9 s.Therefore,the rapid and accurate estimation of the SOM content can provide the strong application potential to the rapid assessment of the soil fertility.

陈柯铭;刘晨曦;韩聪聪;余克强

西北农林科技大学机械与电子工程学院,杨凌 712100西北农林科技大学机械与电子工程学院,杨凌 712100西北农林科技大学机械与电子工程学院,杨凌 712100西北农林科技大学机械与电子工程学院,杨凌 712100||农业农村部农业物联网重点实验室,杨凌 712100||陕西省农业信息感知与智能服务重点实验室,杨凌 712100

农业科技

土壤有机质多光谱便携式含水率

soilorganic mattermultispectralportablemoisture content

《农业工程学报》 2026 (4)

111-120,10

国家重点研发计划项目(2025YFD1700700)陕西省自然科学基础研究计划项目(2022JM-100)

10.11975/j.issn.1002-6819.202505217

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