Exploring the Suitability of UAS-Based Multispectral Images for Estimating Soil Organic Carbon: Comparison with Proximal Soil Sensing and Spaceborne Imagery

Soil organic carbon (SOC) is a variable of vital environmental significance in terms of soil quality and function, global food security, and climate change mitigation. Estimation of its content and prediction accuracy on a broader scale remain crucial. Although, spectroscopy under proximal sensing remains one of the best approaches to accurately predict SOC, however, spectroscopy limitation to estimate SOC on a larger spatial scale remains a concern. Therefore, for an efficient quantification of SOC content, faster and less costly techniques are needed, recent studies have suggested the use of remote sensing approaches. The primary aim of this research was to evaluate and compare the capabilities of small Unmanned Aircraft Systems (UAS) for monitoring and estimation of SOC with those obtained from spaceborne (Sentinel-2) and proximal soil sensing (field spectroscopy measurements) on an agricultural field low in SOC content. Nine calculated spectral indices were added to the remote sensing approaches (UAS and Sentinel-2) to enhance their predictive accuracy. Modeling was carried out using various bands/wavelength (UAS (6), Sentinel-2 (9)) and the calculated spectral indices were used as independent variables to generate soil prediction models using five-fold cross-validation built using random forest (RF) and support vector machine regression (SVMR). The correlation regarding SOC and the selected indices and bands/wavelengths was determined prior to the prediction. Our results revealed that the selected spectral indices slightly influenced the output of UAS compared to Sentinel-2 dataset as the latter had only one index correlated with SOC. For prediction, the models built on UAS data had a better accuracy with RF than the two other data used. However, using SVMR, the field spectral prediction models achieved a better overall result for the entire study (log(1/R), RPD = 1.40; RCV = 0.48; RPIQ = 1.65; RMSEPCV = 0.24), followed by UAS and then Sentinel-2, respectively. This study has shown that UAS imagery can be exploited efficiently using spectral indices.

[1]  P. Hardin,et al.  Detecting Squarrose Knapweed (Centaurea virgata Lam. Ssp. squarrosa Gugl.) Using a Remotely Piloted Vehicle: A Utah Case Study , 2007 .

[2]  Shiliang Liu,et al.  Prediction of soil organic matter variability associated with different land use types in mountainous landscape in southwestern Yunnan province, China , 2015 .

[3]  D. Cozzolino,et al.  Application of near Infrared Reflectance Spectroscopy for the Analysis of Organic C, Total N and pH in Soils of Uruguay , 2002 .

[4]  K. Shepherd,et al.  Development of Reflectance Spectral Libraries for Characterization of Soil Properties , 2002 .

[5]  A. Gitelson,et al.  Use of a green channel in remote sensing of global vegetation from EOS- MODIS , 1996 .

[6]  C. Jordan Derivation of leaf-area index from quality of light on the forest floor , 1969 .

[7]  C. Daughtry,et al.  What good are unmanned aircraft systems for agricultural remote sensing and precision agriculture? , 2018 .

[8]  Giorgos Mallinis,et al.  On the Use of Unmanned Aerial Systems for Environmental Monitoring , 2018, Remote. Sens..

[9]  Mohammadmehdi Saberioon,et al.  Soil organic carbon and texture retrieving and mapping using proximal, airborne and Sentinel-2 spectral imaging , 2018, Remote Sensing of Environment.

[10]  Alex B. McBratney,et al.  Multivariate calibration of hyperspectral γ‐ray energy spectra for proximal soil sensing , 2007 .

[11]  P. Zarco-Tejada,et al.  REMOTE SENSING OF VEGETATION FROM UAV PLATFORMS USING LIGHTWEIGHT MULTISPECTRAL AND THERMAL IMAGING SENSORS , 2009 .

[12]  Mats Söderström,et al.  The use of near infrared (NIR) spectroscopy to improve soil mapping at the farm scale , 2008, Precision Agriculture.

[13]  Neil McKenzie,et al.  Proximal Soil Sensing: An Effective Approach for Soil Measurements in Space and Time , 2011 .

[14]  R. V. Rossel,et al.  Soil organic carbon prediction by hyperspectral remote sensing and field vis-NIR spectroscopy: An Australian case study , 2008 .

[15]  Frédéric Baret,et al.  Assessment of Unmanned Aerial Vehicles Imagery for Quantitative Monitoring of Wheat Crop in Small Plots , 2008, Sensors.

[16]  Sabine Chabrillat,et al.  Prediction of Common Surface Soil Properties Based on Vis-NIR Airborne and Simulated EnMAP Imaging Spectroscopy Data: Prediction Accuracy and Influence of Spatial Resolution , 2016, Remote. Sens..

[17]  John R. Jensen,et al.  Small Unmanned Aerial Systems (sUAS) for environmental remote sensing: challenges and opportunities revisited , 2018, GIScience & Remote Sensing.

[18]  A. J. Richardsons,et al.  DISTINGUISHING VEGETATION FROM SOIL BACKGROUND INFORMATION , 1977 .

[19]  James B. Reeves,et al.  Near Infrared Reflectance Spectroscopy for the Determination of Biological Activity in Agricultural Soils , 2000 .

[20]  J. S. Aber,et al.  Small-Format Aerial Photography: Principles, Techniques and Geoscience Applications , 2010 .

[21]  Baofeng Su,et al.  Significant Remote Sensing Vegetation Indices: A Review of Developments and Applications , 2017, J. Sensors.

[22]  Zhen Guo,et al.  Effects of long-term fertilization on soil organic carbon mineralization and microbial community structure , 2019, PloS one.

[23]  Keith Paustian,et al.  Measuring and monitoring soil organic carbon stocks in agricultural lands for climate mitigation , 2011 .

[24]  Zongming Wang,et al.  Remote estimation of soil organic matter content in the Sanjiang Plain, Northest China: The optimal band algorithm versus the GRA-ANN model , 2016 .

[25]  Sabine Chabrillat,et al.  Soil Organic Carbon Estimation in Croplands by Hyperspectral Remote APEX Data Using the LUCAS Topsoil Database , 2018, Remote. Sens..

[26]  B. Minasny,et al.  Digital Soil Map of the World , 2009, Science.

[27]  A. Held,et al.  High resolution mapping of tropical mangrove ecosystems using hyperspectral and radar remote sensing , 2003 .

[28]  Philippe Lagacherie,et al.  Sensitivity of clay content prediction to spectral configuration of VNIR/SWIR imaging data, from multispectral to hyperspectral scenarios , 2018 .

[29]  Mike J. McLaughlin,et al.  Evaluation of the performance of portable visible-infrared instruments for the prediction of soil properties , 2017 .

[30]  E. Ben-Dor,et al.  Laboratory, field and airborne spectroscopy for monitoring organic carbon content in agricultural soils , 2007 .

[31]  R. Escadafal,et al.  Remote sensing of arid soil surface color with Landsat thematic mapper , 1989 .

[32]  H. Ramon,et al.  On-line measurement of some selected soil properties using a VIS–NIR sensor , 2007 .

[33]  N. Holden,et al.  Optical sensing and chemometric analysis of soil organic carbon – a cost effective alternative to conventional laboratory methods? , 2011 .

[34]  Geert Verhoeven,et al.  Taking computer vision aloft – archaeological three‐dimensional reconstructions from aerial photographs with photoscan , 2011 .

[35]  Naoto Yokoya,et al.  Potential of Resolution-Enhanced Hyperspectral Data for Mineral Mapping Using Simulated EnMAP and Sentinel-2 Images , 2016, Remote. Sens..

[36]  R. J. Hanks,et al.  REFLECTION OF RADIANT ENERGY FROM SOILS , 1965 .

[37]  Daniel Zízala,et al.  Soil Organic Carbon Mapping Using Multispectral Remote Sensing Data: Prediction Ability of Data with Different Spatial and Spectral Resolutions , 2019, Remote. Sens..

[38]  Sabine Grunwald,et al.  Spectroscopic models of soil organic carbon in Florida, USA. , 2010, Journal of environmental quality.

[39]  V. L. Mulder,et al.  The use of remote sensing in soil and terrain mapping — A review , 2011 .

[40]  Andreas Hueni,et al.  Evaluating the capability of the Sentinel 2 data for soil organic carbon prediction in croplands , 2019, ISPRS Journal of Photogrammetry and Remote Sensing.

[41]  Lammert Kooistra,et al.  Soil Organic Carbon mapping of partially vegetated agricultural fields with imaging spectroscopy , 2011, Int. J. Appl. Earth Obs. Geoinformation.

[42]  B. Frazier,et al.  Remote sensing of soils in the eastern Palouse region with Landsat Thematic Mapper , 1989 .

[43]  Perry J. Hardin,et al.  Small‐Scale Remotely Piloted Vehicles in Environmental Research , 2010 .

[44]  Jens Nieke,et al.  APEX - the Hyperspectral ESA Airborne Prism Experiment , 2008, Sensors.

[45]  Agnès Bégué,et al.  Can Commercial Digital Cameras Be Used as Multispectral Sensors? A Crop Monitoring Test , 2008, Sensors.

[46]  M. S. Moran,et al.  Opportunities and limitations for image-based remote sensing in precision crop management , 1997 .

[47]  Lubos Boruvka,et al.  Comparison of Field and Laboratory Wet Soil Spectra in the Vis-NIR Range for Soil Organic Carbon Prediction in the Absence of Laboratory Dry Measurements , 2020, Remote. Sens..

[48]  Nathalie Gorretta,et al.  Clay content mapping from airborne hyperspectral Vis-NIR data by transferring a laboratory regression model , 2017 .

[49]  Kristof Van Oost,et al.  UAS-based soil carbon mapping using VIS-NIR (480–1000nm) multi-spectral imaging: Potential and limitations , 2016 .

[50]  R. Kodešová,et al.  Simple but efficient signal pre-processing in soil organic carbon spectroscopic estimation , 2017 .

[51]  R. V. Rossel,et al.  Visible, near infrared, mid infrared or combined diffuse reflectance spectroscopy for simultaneous assessment of various soil properties , 2006 .

[52]  Kacem Chehdi,et al.  Regional prediction of soil organic carbon content over temperate croplands using visible near-infrared airborne hyperspectral imagery and synchronous field spectra , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[53]  Michael E. Schaepman,et al.  Sentinels for science: potential of Sentinel-1, -2, and -3 missions for scientific observations of ocean, cryosphere, and land , 2012 .

[54]  Cindy Ong,et al.  Reflectance measurements of soils in the laboratory: Standards and protocols , 2015 .

[55]  Alessandro Matese,et al.  A flexible unmanned aerial vehicle for precision agriculture , 2012, Precision Agriculture.

[56]  Clement Atzberger,et al.  First Experience with Sentinel-2 Data for Crop and Tree Species Classifications in Central Europe , 2016, Remote. Sens..

[57]  Paolo Massimo Buscema,et al.  Mapping fractional landscape soils and vegetation components from Hyperion satellite imagery using an unsupervised machine-learning workflow , 2018, Int. J. Digit. Earth.

[58]  H. Tiessen,et al.  Total and organic carbon , 1993 .

[59]  Dong Wang,et al.  Estimating actual crop evapotranspiration using deep stochastic configuration networks model and UAV-based crop coefficients in a pomegranate orchard , 2020, Defense + Commercial Sensing.

[60]  E. Ben-Dor Quantitative remote sensing of soil properties , 2002 .

[61]  R. Clark,et al.  High spectral resolution reflectance spectroscopy of minerals , 1990 .

[62]  Lei Tian,et al.  Development of a low-cost agricultural remote sensing system based on an autonomous unmanned aerial vehicle (UAV) , 2011 .

[63]  James Brasington,et al.  Accuracy assessment of aerial photographs acquired using lighter‐than‐air blimps: low‐cost tools for mapping river corridors , 2009 .

[64]  J. Baluja,et al.  Assessment of vineyard water status variability by thermal and multispectral imagery using an unmanned aerial vehicle (UAV) , 2012, Irrigation Science.

[65]  Huanjun Liu,et al.  Comparison of different satellite bands and vegetation indices for estimation of soil organic matter based on simulated spectral configuration , 2017 .

[66]  A. McBratney,et al.  Near-infrared (NIR) and mid-infrared (MIR) spectroscopic techniques for assessing the amount of carbon stock in soils – Critical review and research perspectives , 2011 .

[67]  K. Shepherd,et al.  Global soil characterization with VNIR diffuse reflectance spectroscopy , 2006 .

[68]  Piero Toscano,et al.  Intercomparison of UAV, Aircraft and Satellite Remote Sensing Platforms for Precision Viticulture , 2015, Remote. Sens..

[69]  Pablo J. Zarco-Tejada,et al.  Estimating evaporation with thermal UAV data and two-source energy balance models , 2016 .

[70]  Christina Bogner,et al.  In‐situ prediction of soil organic carbon by vis–NIR spectroscopy: an efficient use of limited field data , 2017 .

[71]  Ryan R. Jensen,et al.  Small-Scale Unmanned Aerial Vehicles in Environmental Remote Sensing: Challenges and Opportunities , 2011 .

[72]  Li Guo,et al.  Reconciling the discrepancy in ground‐ and satellite‐observed trends in the spring phenology of winter wheat in China from 1993 to 2008 , 2016 .

[73]  A. Huete A soil-adjusted vegetation index (SAVI) , 1988 .

[74]  C. Hugenholtz,et al.  Remote sensing of the environment with small unmanned aircraft systems ( UASs ) , part 1 : a review of progress and challenges 1 , 2014 .

[75]  Eyal Ben-Dor,et al.  Agricultural Soil Spectral Response and Properties Assessment: Effects of Measurement Protocol and Data Mining Technique , 2017, Remote. Sens..

[76]  R. Crippen Calculating the vegetation index faster , 1990 .

[77]  P. Levelt,et al.  ESA's sentinel missions in support of Earth system science , 2012 .

[78]  José Madeira Netto,et al.  Caractéristiques spectrales des surfaces sableuses de la région côtière Nord-Ouest de l'Egypte : application aux données satellitaires SPOT , 1991 .

[79]  W. E. Larson,et al.  Coincident detection of crop water stress, nitrogen status and canopy density using ground-based multispectral data. , 2000 .

[80]  Arko Lucieer,et al.  Direct Georeferencing of Ultrahigh-Resolution UAV Imagery , 2014, IEEE Transactions on Geoscience and Remote Sensing.

[81]  J. S. Aber,et al.  Challenge of Infrared Kite Aerial Photography: A Digital Update , 2009 .

[82]  Junjie Wang,et al.  Improving the prediction of arsenic contents in agricultural soils by combining the reflectance spectroscopy of soils and rice plants , 2016, Int. J. Appl. Earth Obs. Geoinformation.

[83]  Emilien Aldana-Jague,et al.  Assessing the Performance of UAS-Compatible Multispectral and Hyperspectral Sensors for Soil Organic Carbon Prediction , 2019, Sustainability.

[84]  Thomas Lagkas,et al.  A compilation of UAV applications for precision agriculture , 2020, Comput. Networks.

[85]  J. Flexas,et al.  UAVs challenge to assess water stress for sustainable agriculture , 2015 .