Actual evapotranspiration estimation by ground and remote sensing methods: the Australian experience

Glenn, Edward P.; Doody, Tanya M.; Guerschman, Juan Pablo; Huete, Alfredo; King, E. A.; McVicar, Tim R.; Dijk, Albert I. J. M. van; Niel, Tom Van; Yebra, Marta; Zhang, Yongqiang

doi:10.1002/hyp.8391

Cited by 84 publications

(64 citation statements)

References 117 publications

(209 reference statements)

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“…RMSE and MAE for the complete data set and for different subsets (nighttime: 21.00 h-03.00 h UTC, daytime: 6 h-18.00 h UTC, cloud fraction ≥ 0.8, cloud fraction ≥ 0.2-0.8, cloud fraction < 0.2) are computed (Tables 3 and 4). Calculated errors using T rad,WE and T rad,mean (20- , see [3,4] for recent reviews and [88][89][90][91][92] for studies using ground-based data) and below the range of errors reported for eddy covariance (EC) measurements [42], which are here used as reference data. The highest errors (up to 90%) in latent heat flux estimates (using the surface temperature to predict the sensible heat flux) have been reported for natural semiarid areas [8].…”

Section: Suitability Of Model-temperature Combinations To Predict Submentioning

confidence: 99%

“…The diurnal and seasonal cycles of the surface temperature are affected by the relative efficiency of the components of the surface energy balance (SEB) in dissipating the available energy. Thus, SEB key components, such as the turbulent latent (λE) and sensible (H) heat flux, are frequently inferred from observations of the radiometric temperature over a wide range of spatial and temporal scales [1][2][3][4][5][6][7][8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

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Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

et al. 2014

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Abstract:The latent heat flux, one of the key components of the surface energy balance, can be inferred from remotely sensed thermal infrared data. However, discrepancies between modeled and observed evapotranspiration are large. Thermal cameras might provide a suitable tool for model evaluation under variable atmospheric conditions. Here, we evaluate the results from the Penman-Monteith, surface energy balance and Bowen ratio approaches, which estimate the diurnal course of latent heat fluxes at a ripe winter wheat stand using measured and modeled temperatures. Under overcast conditions, the models perform similarly, and radiometric image temperatures are linearly correlated with the inverted aerodynamic temperature. During clear sky conditions, the temperature of the wheat ear layer could be used to predict daytime turbulent fluxes (root mean squared error and mean absolute error: 20-35 W·m 9776Errors are dependent on the models' ability to simulate diurnal hysteresis effects and are largest during intermittent clouds, due to the discrepancy between the timing of image capture and the time needed for the leaf-air-temperature gradient to adapt to changes in solar radiation. During such periods, we suggest using modeled surface temperatures for temporal upscaling and the validation of image data.

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Section: Suitability Of Model-temperature Combinations To Predict Submentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

et al. 2014

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“…Although here the period was not sufficiently long to encompass one growing season. The Commonwealth Science and Industrial Research Organisation (CSIRO) in Australia studied the predictions of eight different ET products, at a minimum monthly frequency and at a spatial resolution of at least 5 km, using flux tower observations and watershed data across the entire continent as part of the Water Information Research and Development Alliance (WIRADA) project (Glenn et al, 2011). The studied ET products were based on different methods including largescale water balance modeling, thermal imagery Jupp, 1999, 2002), spectral imagery , and the global MODIS reflectance-based algorithm .…”

Section: Accuracy Of Spatial Evapotranspiration Datamentioning

confidence: 99%

“…Since the primary purpose of this study was to quantify errors in accumulated ET, only papers that report errors on ET estimates over a minimum period of one growing cycle which on average is about 5-6 months, hereafter called seasonal ET, were consulted. Papers dealing with ET over shorter periods were thus excluded in our review (e.g., Anderson et al, 2011;Chávez et al, 2008;Gonzalez-Dugo et al, 2009;Mu et al, 2011). This, also, implies that GEWEX (Global Energy and Water Exchanges Project)-related field experiments could not be used because intensive campaigns with multiple flux covered periods of weeks only.…”

Section: Accuracy Of Spatial Evapotranspiration Datamentioning

confidence: 99%

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Spatial evapotranspiration, rainfall and land use data in water accounting – Part 1: Review of the accuracy of the remote sensing data

Karimi

Bastiaanssen

2015

Hydrol. Earth Syst. Sci.

128

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Abstract. The scarcity of water encourages scientists to develop new analytical tools to enhance water resource management. Water accounting and distributed hydrological models are examples of such tools. Water accounting needs accurate input data for adequate descriptions of water distribution and water depletion in river basins. Ground-based observatories are decreasing, and not generally accessible. Remote sensing data is a suitable alternative to measure the required input variables. This paper reviews the reliability of remote sensing algorithms to accurately determine the spatial distribution of actual evapotranspiration, rainfall and land use. For our validation we used only those papers that covered study periods of seasonal to annual cycles because the accumulated water balance is the primary concern. Review papers covering shorter periods only (days, weeks) were not included in our review. Our review shows that by using remote sensing, the absolute values of evapotranspiration can be estimated with an overall accuracy of 95 % (SD 5 %) and rainfall with an overall absolute accuracy of 82 % (SD 15 %). Land use can be identified with an overall accuracy of 85 % (SD 7 %). Hence, more scientific work is needed to improve the spatial mapping of rainfall and land use using multiple space-borne sensors. While not always perfect at all spatial and temporal scales, seasonally accumulated actual evapotranspiration maps can be used with confidence in water accounting and hydrological modeling.

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Remote Sensing of Environmental Variables and Fluxes

Sadeghi

Babaeian

Ebtehaj

et al. 2018

Handbook of Environmental Engineering

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Actual evapotranspiration estimation by ground and remote sensing methods: the Australian experience

Cited by 84 publications

References 117 publications

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

Diurnal Dynamics of Wheat Evapotranspiration Derived from Ground-Based Thermal Imagery

Spatial evapotranspiration, rainfall and land use data in water accounting – Part 1: Review of the accuracy of the remote sensing data

Remote Sensing of Environmental Variables and Fluxes

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