Effect of the revisit interval and temporal upscaling methods on the accuracy of remotely sensed evapotranspiration estimates

Alfieri, Joseph G.; Anderson, Martha C.; Kustas, William P.; Cammalleri, Carmelo

doi:10.5194/hess-21-83-2017

Cited by 37 publications

(33 citation statements)

References 101 publications

(73 reference statements)

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“…It has to be mentioned that the conversion of instantaneous ET to the daily scale is performed for the same day primarily because of (1) the daily revisit period of the MODIS sensor that provides widely applied land products and (2) the possibly decreased validity of the constancy assumption made in the conversion methods over a longer time scale [ Alfieri et al ., ]. The effectiveness of the improved method during subsequent days is beyond the scope of this paper and is therefore not investigated in the current study.…”

Section: Resultsmentioning

confidence: 99%

An improved constant evaporative fraction method for estimating daily evapotranspiration from remotely sensed instantaneous observations

Tang

2017

Geophysical Research Letters

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Evapotranspiration (ET) is a primary mechanism for water and heat transfer between land and the atmosphere. One approach to estimate ET is from instantaneous remotely sensed data. The constant evaporative fraction (EF) method is then usually used to estimate integrated daily fluxes, which are typically underestimated values. Here we present a theoretical improvement to the conventional EF. The improved EF is shown to be robust and superior to the conventional approach, and it significantly reduces the underestimation bias.

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Section: Resultsmentioning

confidence: 99%

An improved constant evaporative fraction method for estimating daily evapotranspiration from remotely sensed instantaneous observations

Tang

2017

Geophysical Research Letters

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“…This study showed that SVEN can be used as a tool to temporally interpolate land surface variables between remote sensing acquisitions with few meteorological data. In the statistical approaches, Alfieri et al (2017) identified that a return interval of remote sensing observations should be no less than 5 days to accurately interpolate daily ET with relative errors less than 20%.…”

Section: Potential Applications and Improvement Of Sven Modelmentioning

confidence: 99%

“…However, both optical and thermal satellite observations present gaps during cloudy periods, and those gaps may coincide with the time when such information is mostly needed (Westermann et al, 2011), for instance the high frequency of cloudy weather during the crop growing season in monsoonal regimes (García et al, 2013) and high latitude regions (Wang et al, 2018a). Methods are needed to temporally interpolate and upscale the instantaneous records into continuous daily, monthly or annual values (Alfieri et al, 2017;Huang et al, 2016). As one of the most exciting recent advances in near-Earth 10 observation, Unmanned Aerial Systems (UAS) can flexibly fly at a low altitude (< 100-200 m) with favourable revisit times and low cost (Berni et al, 2009;McCabe et al, 2017).…”

mentioning

confidence: 99%

“…Ts, Rn, SM, ET and GPP, using statistical interpolation could be challenging with low revisit frequency. For 25 instance, Alfieri et al (2017) found that a return interval of EO observations of no less than 5 days was necessary to statistically interpolate daily ET with relative errors smaller than 20%. To interpolate low persistence variables between remote sensing acquisitions, a dynamic model based interpolation approach considering the dynamics of the land surface energy balance can be better.…”

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confidence: 99%

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Temporal interpolation of land surface fluxes derived from remote sensing – results with an Unmanned Aerial System

Garcı́a¹,

Ibrom²,

Bauer‐Gottwein³

2019

Preprint

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Abstract. Remote sensing imagery can provide snapshots of rapidly changing land surface variables, e.g. evapotranspiration (ET), land surface temperature (Ts), net radiation (Rn), soil moisture (SM) and gross primary productivity (GPP), for the time of sensor overpass. However, discontinuous data acquisitions limit the applicability of remote sensing for water resources and ecosystem management. Methods to interpolate between remote sensing snapshot data and to upscale them from instantaneous to daily time scale are needed. We developed a dynamic Soil Vegetation Atmosphere Transfer model to interpolate land surface state variables that change rapidly between remote sensing observations. The Soil-Vegetation, Energy, water and CO2 traNsfer model (SVEN), which combines the snapshot version of the remote sensing Priestley Taylor Jet Propulsion Laboratory ET model and light use efficiency GPP models, incorporates now a dynamic component for the ground heat flux based on the force-restore method and a water balance bucket model to estimate SM and canopy wetness at half-hourly time step. A case study was conducted to demonstrate the method using optical and thermal data from an Unmanned Aerial System in a willow plantation flux site (Risoe, Denmark). Based on model parameter calibration with the snapshots of land surface variables at the time of flight, SVEN interpolated the snapshot Ts, Rn, SM, ET and GPP to continuous records for the growing season of 2016 with forcing from continuous climatic data and NDVI. Validation with eddy covariance and other in-situ observations indicates that SVEN can well estimate daily land surface fluxes between remote sensing acquisitions with root mean square deviations of the simulated daily Ts, Rn, SM, LE and GPP equal to 2.35 °C, 14.49 W m−2, 1.98 % m3 m−3, 16.62 W m−2 and 3.01 g C m−2 d−1, respectively. This study demonstrates that, in this deciduous tree planation, temporally sparse optical and thermal remote sensing observations can be used as ground truth to calibrate soil and vegetation parameters of a simple land surface modelling scheme to estimate low persistence or rapidly changing land surface variables with the use of few forcing variables. This approach can also be applied with remotely sensed data from other platforms to fill temporal gaps, e.g. cloud induced data gaps in satellite observation.

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“…(4). In fact, it is clear that some profiles can be parabolic in shape (i.e., demonstrate an inflection point), especially immediately after rain events (dynamic case), or due to sharp changes in soil characteristics (Al-Hamdan and Cruise, 2010;Mishra et al, 2015) (see Fig. A1).…”

Section: Profile Developmentmentioning

confidence: 99%

Correction of table-2

Mishra¹

2017

Preprint

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The principle of maximum entropy (POME) can be used to develop vertical soil moisture (SM) profiles. The minimal inputs required by the POME model make it an excellent choice for remote sensing applications. Two of the major input requirements of the POME model are the surface boundary condition and profile-mean moisture content. Microwave-based SM estimates from the Advanced Microwave Scanning Radiometer (AMSR-E) can supply the surface boundary condition whereas thermal infrared-based moisture estimated from the Atmospheric Land EXchange Inverse (ALEXI) surface energy balance model can provide the mean moisture condition. A disaggregation approach was followed to downscale coarse-resolution ( ∼ 25 km) microwave SM estimates to match the finer resolution (∼ 5 km) thermal data. The study was conducted over multiple years (2006)(2007)(2008)(2009)(2010) in the southeastern US. Disaggregated soil moisture estimates along with the developed profiles were compared with the Noah land surface model (LSM), as well as in situ measurements from 10 Natural Resource Conservation Services (NRCS) Soil Climate Analysis Network (SCAN) sites spatially distributed within the study region. The overall disaggregation results at the SCAN sites indicated that in most cases disaggregation improved the temporal correlations with unbiased root mean square differences (ubRMSD) in the range of 0.01-0.09 m 3 m −3 . The profile results at SCAN sites showed a mean bias of 0.03 and 0.05 (m 3 m −3 ); ubRMSD of 0.05 and 0.06 (m 3 m −3 ); and correlation coefficient of 0.44 and 0.48 against SCAN observa-tions and Noah LSM, respectively. Correlations were generally highest in agricultural areas where values in the 0.6-0.7 range were achieved.

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Effect of the revisit interval and temporal upscaling methods on the accuracy of remotely sensed evapotranspiration estimates

Cited by 37 publications

References 101 publications

An improved constant evaporative fraction method for estimating daily evapotranspiration from remotely sensed instantaneous observations

An improved constant evaporative fraction method for estimating daily evapotranspiration from remotely sensed instantaneous observations

Temporal interpolation of land surface fluxes derived from remote sensing – results with an Unmanned Aerial System

Correction of table-2

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