On the interchangeability of Landsat and MODIS data in the CMRSET actual evapotranspiration model – Comment on “Monitoring irrigation using Landsat observations and climate data over regional scales in the Murray-Darling Basin” by David Bretreger, In-Young Yeo, Greg Hancock and Garry Willgoose

•We demonstrate flaws in the CMRSET implementation in Bretreger et al. (2020).•Actual evapotranspiration biases were because they used an incorrect Landsat band.•The calculation of GVMI should have used Landsat SWIR1 band instead of SWIR2.•CMRSET’s suitability for irrigation monitoring is demonstrat...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2021-12, Vol.603, p.127044, Article 127044
Main Authors: Peña-Arancibia, Jorge L., McVicar, Tim R., Kong, Dongdong, Guerschman, Juan P., Van Niel, Thomas G., Vleeshower, Jamie, Li, Ling Tao
Format: Article
Language:English
Subjects:
Actual evapotranspiration
Crop coefficient
Irrigation water use
Remote sensing
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Summary:•We demonstrate flaws in the CMRSET implementation in Bretreger et al. (2020).•Actual evapotranspiration biases were because they used an incorrect Landsat band.•The calculation of GVMI should have used Landsat SWIR1 band instead of SWIR2.•CMRSET’s suitability for irrigation monitoring is demonstrated via new experiments.•CMRSET evapotranspiration using the correct SWIR1 band did not show large biases. In a recent paper published in this journal, Bretreger et al. (2020) estimate irrigation water use from satellite remotely sensed estimates of actual evapotranspiration in five irrigated districts of the Murray-Darling Basin (southeast Australia). They used three models that scale crop reference evapotranspiration with vegetation indices acquired by recent Landsat satellites: (i) IrriSAT, (ii) Kamble and (iii) CMRSET. In their paper, irrigation water use computed with CMRSET generally overestimated observed irrigation water use, sometimes fivefold. Based on these results, Bretreger et al. (2020) discouraged the use of CMRSET for irrigation monitoring. In this comment, we reproduce the experiments in Bretreger et al. (2020), and demonstrate that their overestimation was because they used an incorrect Landsat band in their implementation of CMRSET. CMRSET was originally calibrated using both MODIS-derived Enhanced Vegetation Index (EVI) and Global Vegetation Moisture Index (GVMI). To calculate GVMI, a shortwave infrared (SWIR) band with a wavelength of ∼1.6 μm was used, which for MODIS is named SWIR2, and for Landsat is named SWIR1 (i.e., different sensors have different bands and a different number of bands and SWIR1 in MODIS has a wavelength of ∼1.2 μm). In their Landsat CMRSET implementation, Bretreger et al. (2020) computed GVMI using the Landsat SWIR2 band, which has a wavelength of ∼2.1 μm (see their Table 3). We show that CMRSET implemented with the Landsat SWIR1 band (i.e., with a wavelength of ∼1.6 μm, so being the correct Landsat band to calculate GVMI) yields similar results (both for temporal patterns and magnitude) when compared to the other two remote sensing actual evapotranspiration models in Bretreger et al. (2020). For the irrigation districts, these similar results meant that the mean water year (i.e., July to next June from 2010 to 2017) actual evapotranspiration mean absolute relative difference was 15.3% (with a 5.4%–26.5% range) and the water year irrigation water use mean absolute relative difference was 4.1% (with a 9.8%–18.9% range).
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2021.127044