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土壤 pH 值的现场传感器测绘。

Soil pH mapping with an on-the-go sensor.

机构信息

Leibniz-Institute for Agricultural Engineering, Department of Engineering for Crop Production, Max-Eyth-Allee 100, D-14469 Potsdam, Germany.

出版信息

Sensors (Basel). 2011;11(1):573-98. doi: 10.3390/s110100573. Epub 2011 Jan 7.

DOI:10.3390/s110100573
PMID:22346591
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3274122/
Abstract

Soil pH is a key parameter for crop productivity, therefore, its spatial variation should be adequately addressed to improve precision management decisions. Recently, the Veris pH Manager™, a sensor for high-resolution mapping of soil pH at the field scale, has been made commercially available in the US. While driving over the field, soil pH is measured on-the-go directly within the soil by ion selective antimony electrodes. The aim of this study was to evaluate the Veris pH Manager™ under farming conditions in Germany. Sensor readings were compared with data obtained by standard protocols of soil pH assessment. Experiments took place under different scenarios: (a) controlled tests in the lab, (b) semicontrolled test on transects in a stop-and-go mode, and (c) tests under practical conditions in the field with the sensor working in its typical on-the-go mode. Accuracy issues, problems, options, and potential benefits of the Veris pH Manager™ were addressed. The tests demonstrated a high degree of linearity between standard laboratory values and sensor readings. Under practical conditions in the field (scenario c), the measure of fit (r(2)) for the regression between the on-the-go measurements and the reference data was 0.71, 0.63, and 0.84, respectively. Field-specific calibration was necessary to reduce systematic errors. Accuracy of the on-the-go maps was considerably higher compared with the pH maps obtained by following the standard protocols, and the error in calculating lime requirements was reduced by about one half. However, the system showed some weaknesses due to blockage by residual straw and weed roots. If these problems were solved, the on-the-go sensor investigated here could be an efficient alternative to standard sampling protocols as a basis for liming in Germany.

摘要

土壤 pH 值是作物生产力的关键参数,因此,为了提高精准管理决策的水平,应该充分考虑其空间变异性。最近,Veris pH Manager™传感器已经在美国商业化,可用于在田间尺度上高分辨率地绘制土壤 pH 值。在田间行驶时,通过离子选择性锑电极直接在土壤中进行土壤 pH 值的现场测量。本研究旨在评估 Veris pH Manager™在德国农业条件下的表现。传感器读数与通过标准土壤 pH 值评估方案获得的数据进行了比较。实验在不同的场景下进行:(a)实验室控制测试,(b)在停走模式下的横断面半控制测试,以及(c)田间实际条件下的测试,传感器以典型的行进中模式工作。解决了 Veris pH Manager™的准确性问题、问题、选项和潜在优势。测试表明,标准实验室值与传感器读数之间具有高度的线性关系。在田间实际条件下(情景 c),行进中测量值与参考数据之间的拟合度(r²)分别为 0.71、0.63 和 0.84。需要进行田间特定的校准,以减少系统误差。与遵循标准方案获得的 pH 值图相比,行进中地图的准确性要高得多,计算石灰需求量的误差减少了约一半。然而,该系统由于残留的秸秆和杂草根的堵塞而存在一些弱点。如果这些问题得到解决,那么这里研究的行进中传感器可能成为德国石灰应用标准采样方案的有效替代方案。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c19e/3274122/6295536277fe/sensors-11-00573f11.jpg
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