Assessing the performance of UAS-compatible multispectral and hyperspectral sensors for soil organic carbon prediction
Autor: | Kristof Van Oost, Bas van Wesemael, Emilien Aldana-Jague, Giacomo Crucil, Fabio Castaldi, Andy Macdonald |
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Přispěvatelé: | UCL - SST/ELI/ELIC - Earth & Climate |
Předmět: |
010504 meteorology & atmospheric sciences
Monitoring Geography Planning and Development Multispectral image lcsh:TJ807-830 lcsh:Renewable energy sources Management Monitoring Policy and Law 01 natural sciences Calibration Renewable Energy Spatial analysis Multispectral sensors lcsh:Environmental sciences 0105 earth and related environmental sciences Remote sensing lcsh:GE1-350 Planning and Development Topsoil Sustainability and the Environment Geography Policy and Law Precision agriculture Renewable Energy Sustainability and the Environment Soil organic carbon lcsh:Environmental effects of industries and plants Hyperspectral imaging Sampling (statistics) 04 agricultural and veterinary sciences Building and Construction Management Hyperspectral sensors lcsh:TD194-195 040103 agronomy & agriculture 0401 agriculture forestry and fisheries Environmental science Proximal sensing Interpolation |
Zdroj: | Sustainability Volume 11 Issue 7 Sustainability (Online), Vol. 11, no.7, p. 1889 (2019) Sustainability, Vol 11, Iss 7, p 1889 (2019) |
DOI: | 10.3390/su11071889 |
Popis: | Laboratory spectroscopy has proved its reliability for estimating soil organic carbon (SOC) by exploiting the relationship between electromagnetic radiation and key spectral features of organic carbon located in the VIS-NIR-SWIR (350&ndash 2500 nm) region. While this approach provides SOC estimates at specific sampling points, geo-statistical or interpolation techniques are required to infer continuous spatial information. UAS-based proximal or remote sensing has the potential to provide detailed and spatially explicit spectral sampling of the topsoil at the field or even watershed scale. However, the factors affecting the quality of spectral acquisition under outdoor conditions need to be considered. In this study, we investigate the capabilities of two portable hyperspectral sensors (STS-VIS and STS-NIR), and two small-form multispectral cameras with narrow bands in the VIS-NIR region (Parrot Sequoia and Mini-MCA6), to predict SOC content. We collected spectral data under both controlled laboratory and outdoor conditions, with the latter being affected by variable illumination and atmospheric conditions and sensor-sample distance. We also analysed the transferability of the prediction models between different measurement setups by aligning spectra acquired under different conditions (laboratory and outdoor) or by different instruments. Our results indicate that UAS-compatible small-form sensors can be used to reliably estimate SOC. The results show that: (i) the best performance for SOC estimation under outdoor conditions was obtained using the VIS-NIR range, while the addition of the SWIR region decreased the prediction accuracy (ii) prediction models using only the narrow bands of multispectral cameras gave similar or better performances than those using continuous spectra from the STS hyperspectral sensors and (iii) when used in outdoor conditions, the micro hyperspectral sensors substantially benefitted from a laboratory model calibration followed by a spectral transfer using an internal soil standard. Based on this analysis, we recommend VIS-NIR portable instruments for estimating spatially distributed SOC data. The integration of these sensors in UAS-mapping devices could represent a cost-effective solution for soil research and precision farming applications when high resolution data are required. |
Databáze: | OpenAIRE |
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