Zappa, Luca

Schlaffer, Stefan

Brocca, Luca

Vreugdenhil, Mariette

Dorigo, Wouter Arnoud

2022-09-20T08:16:53Z

2022-09-20T08:16:53Z

2022-05-25

<div class="csl-bib-body"> <div class="csl-entry">Zappa, L., Schlaffer, S., Brocca, L., Vreugdenhil, M., &#38; Dorigo, W. A. (2022, May 25). <i>How accurately can we retrieve irrigation timing and water amounts from (satellite) soil moisture?</i> [Conference Presentation]. ESA Living Planet Symposium 2022, Bonn, Germany. http://hdl.handle.net/20.500.12708/80467</div> </div>

http://hdl.handle.net/20.500.12708/80467

While ensuring food security worldwide, irrigation is altering the water cycle and generating numerous environmental side effects, such as groundwater depletion and soil salinization. As detailed knowledge about location, timing and amounts of water used for irrigation over large areas is still lacking, remotely sensed soil moisture has proved to be a convenient means to fill this gap. However, the spatial resolution and/or the revisit time of satellite products represent a major limitation to accurately estimating irrigation. In this work, we systematically and quantitatively assess the impact of the spatio-temporal resolution of soil moisture observations on the reliability of the retrieved irrigation information, i.e., timing and water amounts. Through a synthetic experiment based on soil moisture timeseries simulated by a hydrological model, we evaluate first the individual and then the combined impact of varying spatial and temporal resolution on both the detection and quantification accuracy. Furthermore, we investigate the effect of instrument noise typical of current satellite sensors, i.e., retrieval error, and irrigation rate, i.e., irrigation system and/or farmer’s decision on how much to irrigate. Satisfactory results, both in terms of detection (F-score > 0.8) and quantification (Pearson’s R > 0.8), are found with soil moisture temporal samplings up to 3 days, or irrigated fractions as low as 30%, i.e., at least one-third of the pixel covers the irrigated field(s). Although lower spatial and temporal resolutions lead to a decrease in detection and quantification accuracy, the presence of random noise in the soil moisture timeseries has a more significant negative impact. As expected, better performances are found when higher volumes of irrigation water reach the soil. Finally, we show that current high-resolution satellite soil moisture products (e.g., from Sentinel-1) agree significantly better with model simulations forced with irrigation compared to rainfed simulations. On the other hand, coarse-scale products achieve higher correlations with soil moisture simulated without irrigation. Hence, our analysis highlights the potential for employing Sentinel-1 derived soil moisture for field-scale irrigation monitoring.

en

soil moisture

How accurately can we retrieve irrigation timing and water amounts from (satellite) soil moisture?

Presentation

Vortrag

Research Institute for Geo-Hydrological Protection, Italy

Conference Presentation

E4

Environmental Monitoring and Climate Adaptation

100

E120-01-2 - Forschungsgruppe Klima- und Umweltfernerkundung

E120-01-1 - Forschungsgruppe Mikrowellenfernerkundung

0000-0003-4742-8648

0000-0002-9080-260X

ESA Living Planet Symposium 2022

23-05-2022

27-05-2022

Hybrid

Event for scientific audience

Bonn

DE

ESA

Zappa, Luca

Sonstige und interdisziplinäre Geowissenschaften

1059

100

none

no Fulltext

http://purl.org/coar/resource_type/c_18cp

Publications

en

conference paper not in proceedings

E120-08 - Forschungsbereich Klima- und Umweltfernerkundung

E120 - Department für Geodäsie und Geoinformation

National Research Council

E120-01 - Forschungsbereich Fernerkundung

E120-08 - Forschungsbereich Klima- und Umweltfernerkundung

0000-0003-4742-8648

0000-0002-9080-260X

0000-0001-8054-7572

E120 - Department für Geodäsie und Geoinformation

E100 - Fakultät für Mathematik und Geoinformation

E120 - Department für Geodäsie und Geoinformation

E120 - Department für Geodäsie und Geoinformation