Diurnal and Seasonal Mapping of Water Deficit Index and Evapotranspiration by an Unmanned Aerial System: A Case Study for Winter Wheat in Denmark

Precision irrigation is a promising method to mitigate the impacts of drought stress on crop production with the optimal use of water resources. However, the reliable assessment of plant water status has not been adequately demonstrated, and unmanned aerial systems (UAS) offer great potential for spatiotemporal improvements. This study utilized UAS equipped with multispectral and thermal sensors to detect and quantify drought stress in winter wheat (Triticum aestivum L.) using the Water Deficit Index (WDI). Biennial field experiments were conducted on coarse sand soil in Denmark and analyses were performed at both diurnal and seasonal timescales. The WDI was significantly correlated with leaf stomatal conductance (R2 = 0.61–0.73), and the correlation was weaker with leaf water potential (R2 = 0.39–0.56) and topsoil water status (the highest R2 of 0.68). A semi-physical model depicting the relationship between WDI and fraction of transpirable soil water (FTSW) in the root zone was derived with R2 = 0.74. Moreover, WDI estimates were improved using an energy balance model with an iterative scheme to estimate the net radiation and land surface temperature, as well as the dual crop coefficient. The diurnal variation in WDI revealed a pattern of the ratio of actual to potential evapotranspiration, being higher in the morning, decreasing at noon hours and ‘recovering’ in the afternoon. Future work should investigate the temporal upscaling of evapotranspiration, which may be used to develop methods for site-specific irrigation recommendations.

[1]  William P. Kustas,et al.  A reexamination of the crop water stress index , 1988, Irrigation Science.

[2]  V. Cantore,et al.  The Application of Ground-Based and Satellite Remote Sensing for Estimation of Bio-Physiological Parameters of Wheat Grown Under Different Water Regimes , 2020, Water.

[3]  I. Trigo,et al.  A New Method to Estimate Reference Crop Evapotranspiration from Geostationary Satellite Imagery: Practical Considerations , 2019, Water.

[4]  Jayme Garcia Arnal Barbedo,et al.  A Review on the Use of Unmanned Aerial Vehicles and Imaging Sensors for Monitoring and Assessing Plant Stresses , 2019, Drones.

[5]  N. Turner Measurement of plant water status by the pressure chamber technique , 1988, Irrigation Science.

[6]  D. Raes,et al.  AquaCrop — The FAO Crop Model to Simulate Yield Response to Water: II. Main Algorithms and Software Description , 2009 .

[7]  O. H. Jacobsen,et al.  A laboratory calibration of time domain reflectometry for soil water measurement including effects of bulk density and texture , 1993 .

[8]  Kathy Steppe,et al.  Optimizing the Processing of UAV-Based Thermal Imagery , 2017, Remote. Sens..

[9]  Giuseppe Modica,et al.  Applications of UAV Thermal Imagery in Precision Agriculture: State of the Art and Future Research Outlook , 2020, Remote. Sens..

[10]  Rabi N. Sahoo,et al.  Application of thermal imaging and hyperspectral remote sensing for crop water deficit stress monitoring , 2019, Geocarto International.

[11]  Andrea Berton,et al.  Estimation of Water Stress in Grapevines Using Proximal and Remote Sensing Methods , 2018, Remote. Sens..

[12]  P. Ciais,et al.  Global irrigation contribution to wheat and maize yield , 2021, Nature Communications.

[13]  A. Ibrom,et al.  Temporal interpolation of land surface fluxes derived from remote sensing – results with an unmanned aerial system , 2020 .

[14]  Y. Cohen,et al.  Estimation of leaf water potential by thermal imagery and spatial analysis. , 2005, Journal of experimental botany.

[15]  Craig S. T. Daughtry,et al.  Estimation of the soil heat flux/net radiation ratio from spectral data , 1990 .

[16]  Serhiy Skakun,et al.  Remote sensing based yield monitoring: Application to winter wheat in United States and Ukraine , 2019, Int. J. Appl. Earth Obs. Geoinformation.

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

[18]  D. Lawlor,et al.  The effects of drought on barley growth: models and measurements showing the relative importance of leaf area and photosynthetic rate , 1979, The Journal of Agricultural Science.

[19]  William P. Kustas,et al.  Upscaling of evapotranspiration fluxes from instantaneous to daytime scales for thermal remote sensing applications , 2013 .

[20]  M. Andersen,et al.  A review of drought adaptation in crop plants: changes in vegetative and reproductive physiology induced by ABA-based chemical signals , 2005 .

[21]  E. Fereres,et al.  Using high resolution UAV thermal imagery to assess the variability in the water status of five fruit tree species within a commercial orchard , 2013, Precision Agriculture.

[22]  L. G. Santesteban,et al.  High-resolution UAV-based thermal imaging to estimate the instantaneous and seasonal variability of plant water status within a vineyard , 2017 .

[23]  H. Nieto,et al.  Crop water stress maps for an entire growing season from visible and thermal UAV imagery , 2016 .

[24]  Paul D. Colaizzi,et al.  Water Stress Detection Under High Frequency Sprinkler Irrigation with Water Deficit Index , 2003 .

[25]  Satoshi Ogawa,et al.  Drought Response in Wheat: Key Genes and Regulatory Mechanisms Controlling Root System Architecture and Transpiration Efficiency , 2017, Front. Chem..

[26]  M. S. Moran,et al.  Estimating crop water deficit using the relation between surface-air temperature and spectral vegetation index , 1994 .

[27]  Guirui Yu,et al.  Simulation of diurnal variations of CO2, water and heat fluxes over winter wheat with a model coupled photosynthesis and transpiration , 2006 .

[28]  S. Hansen,et al.  Crop coefficients for winter wheat in a sub-humid climate regime , 2008 .

[29]  Thomas Udelhoven,et al.  Challenges and Future Perspectives of Multi-/Hyperspectral Thermal Infrared Remote Sensing for Crop Water-Stress Detection: A Review , 2019, Remote. Sens..

[30]  K. Jung,et al.  Crosstalk between diurnal rhythm and water stress reveals an altered primary carbon flux into soluble sugars in drought-treated rice leaves , 2017, Scientific Reports.

[31]  M. El-Shirbeny,et al.  Wheat Yield Response to Water Deficit under Central Pivot Irrigation System Using Remote Sensing Techniques , 2015 .

[32]  R. Schreiner,et al.  Appropriate Time to Measure Leaf and Stem Water Potential in North-South Oriented, Vertically Shoot-Positioned Vineyards , 2020, American Journal of Enology and Viticulture.

[33]  N. Brozović,et al.  Satellite‐Based Monitoring of Irrigation Water Use: Assessing Measurement Errors and Their Implications for Agricultural Water Management Policy , 2020, Water Resources Research.

[34]  Yoshio Inoue,et al.  Analysis of Airborne Optical and Thermal Imagery for Detection of Water Stress Symptoms , 2018, Remote. Sens..

[35]  E. S. Köksal Irrigation water management with water deficit index calculated based on oblique viewed surface temperature , 2008, Irrigation Science.

[36]  I. Burton,et al.  Achieving Adequate Adaptation in Agriculture , 2005 .

[37]  Y. Zha,et al.  Nonlinear boundaries of land surface temperature–vegetation index space to estimate water deficit index and evaporation fraction , 2019 .

[38]  Wenting Han,et al.  UAV Multispectral Imagery Combined with the FAO-56 Dual Approach for Maize Evapotranspiration Mapping in the North China Plain , 2019, Remote. Sens..

[39]  M. Andersen,et al.  Use of the root contact concept, an empirical leaf conductance model and pressure-volume curves in simulating crop water relations , 1993, Plant and Soil.

[40]  Wen Wang,et al.  Wind Speed-Independent Two-Source Energy Balance Model Based on a Theoretical Trapezoidal Relationship between Land Surface Temperature and Fractional Vegetation Cover for Evapotranspiration Estimation , 2020 .

[41]  I. F. Long,et al.  Turbulent diffusion within a wheat canopy: II. Results and interpretation , 1975 .

[42]  J. Norman,et al.  Evaluation of soil and vegetation heat flux predictions using a simple two-source model with radiometric temperatures for partial canopy cover , 1999 .

[43]  Flavio Esposito,et al.  UAV-Based High Resolution Thermal Imaging for Vegetation Monitoring, and Plant Phenotyping Using ICI 8640 P, FLIR Vue Pro R 640, and thermoMap Cameras , 2019, Remote. Sens..

[44]  M. S. Moran,et al.  Canopy temperature variability as an indicator of crop water stress severity , 2006, Irrigation Science.

[45]  Yuanyuan Li,et al.  Improving water-use efficiency by decreasing stomatal conductance and transpiration rate to maintain higher ear photosynthetic rate in drought-resistant wheat , 2017 .

[46]  G. Gutman,et al.  The derivation of the green vegetation fraction from NOAA/AVHRR data for use in numerical weather prediction models , 1998 .

[47]  Peter Bauer-Gottwein,et al.  Mapping Root-Zone Soil Moisture Using a Temperature-Vegetation Triangle Approach with an Unmanned Aerial System: Incorporating Surface Roughness from Structure from Motion , 2018, Remote. Sens..