Proximal and remote sensing – what makes the best farm digital soil maps?

IF 1.2 4区农林科学 Q4 SOIL SCIENCE Soil Research Pub Date : 2024-02-16 DOI:10.1071/sr23112

Patrick Filippi, Brett M. Whelan, Thomas F. A. Bishop

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Abstract

Context

Digital soil maps (DSM) across large areas have an inability to capture soil variation at within-fields despite being at fine spatial resolutions. In addition, creating field-extent soil maps is relatively rare, largely due to cost.

Aims

To overcome these limitations by creating soil maps across multiple fields/farms and assessing the value of different remote sensing (RS) and on-the-go proximal (PS) datasets to do this.

Methods

The value of different RS and on-the-go PS data was tested individually, and in combination for mapping three different topsoil and subsoil properties (organic carbon, clay, and pH) for three cropping farms across Australia using DSM techniques.

Key results

Using both PS and RS data layers created the best predictions. Using RS data only generally led to better predictions than PS data only, likely because soil variation is driven by a number of factors, and there is a larger suite of RS variables that represent these. Despite this, PS gamma radiometrics potassium was the most widely used variable in the PS and RS scenario. The RS variables based on satellite imagery (NDVI and bare earth) were important predictors for many models, demonstrating that imagery of crops and bare soil represent variation in soil well.

Conclusions

The results demonstrate the value of combining both PS and RS data layers together to map agronomically important topsoil and subsoil properties at fine spatial resolutions across diverse cropping farms.

Implications

Growers that invest in implementing this could then use these products to inform important decisions regarding management of soil and crops.

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近景和遥感--怎样才能绘制出最好的农田数字土壤图？

背景大面积的数字土壤图（DSM）尽管空间分辨率很高，但却无法捕捉田地内部的土壤变化。此外，主要由于成本原因，绘制田块范围的土壤图相对较少。目的通过绘制多块田地/农场的土壤地图来克服这些局限性，并评估不同遥感（RS）和随行近地（PS）数据集的价值。方法测试了不同遥感和实时近地 PS 数据各自的价值，以及结合使用 DSM 技术为澳大利亚三个种植农场绘制三种不同表土和底土性质（有机碳、粘土和 pH 值）地图的价值。主要结果同时使用 PS 和 RS 数据层可得出最佳预测结果。只使用 RS 数据通常比只使用 PS 数据预测结果更好，这可能是因为土壤变化是由多种因素驱动的，而 RS 变量中代表这些因素的变量较多。尽管如此，在 PS 和 RS 方案中，PS 伽马辐射测量钾是使用最广泛的变量。基于卫星图像的 RS 变量（归一化差异植被指数和裸地）是许多模型的重要预测因子，这表明作物和裸土图像能很好地代表土壤的变化。结论结果表明，将 PS 和 RS 数据层结合在一起，以精细的空间分辨率绘制不同种植农场中具有重要农艺意义的表土和底土属性图，具有重要价值。意义投资实施这项技术的种植者可以利用这些产品为有关土壤和作物管理的重要决策提供信息。

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

Soil Research SOIL SCIENCE-

CiteScore

3.20

自引率

6.20%

发文量

审稿时长

4.5 months

期刊介绍： Soil Research (formerly known as Australian Journal of Soil Research) is an international journal that aims to rapidly publish high-quality, novel research about fundamental and applied aspects of soil science. As well as publishing in traditional aspects of soil biology, soil physics and soil chemistry across terrestrial ecosystems, the journal welcomes manuscripts dealing with wider interactions of soils with the environment. Soil Research is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science.