Retrieving the irrigation actually applied at district scale: Assimilating high-resolution Sentinel-1-derived soil moisture data into a FAO-56-based model

• Published in: Agricultural water management Vol. 293; p. 108704
• Main Authors: Laluet, Pierre, Olivera-Guerra, Luis Enrique, Altés, Víctor, Paolini, Giovanni, Ouaadi, Nadia, Rivalland, Vincent, Jarlan, Lionel, Villar, Josep Maria, Merlin, Olivier
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.03.2024; Elsevier Masson; Elsevier
• Subjects: Continental interfaces, environment; Data assimilation; deficit irrigation; Irrigation amounts; irrigation rates; irrigation scheduling; Microwave; Ocean, Atmosphere; Remote sensing; Sciences of the Universe; Soil moisture; soil water; Spain; uncertainty; Water balance model; Spain; Microwave; Soil moisture; Water balance model; Irrigation amounts; Remote sensing; Data assimilation; Irrigation amounts Data assimilation Soil moisture Water balance model Remote sensing Microwave
• ISSN: 0378-3774; 1873-2283
• DOI: 10.1016/j.agwat.2024.108704

Irrigation is the most water consuming activity in the world. Knowing the timing and amount of irrigation that is actually applied is therefore fundamental for water managers. However, this information is rarely available at all scales and is subject to large uncertainties due to the wide variety of existing agricultural practices and associated irrigation regimes (full irrigation, deficit irrigation, or over-irrigation). To fill this gap, we propose a two-step approach based on 15 m resolution Sentinel-1 (S1) surface soil moisture (SSM) data to retrieve the actual irrigation at the weekly scale over an entire irrigation district. In a first step, the S1-derived SSM is assimilated into a FAO-56-based crop water balance model (SAMIR) to retrieve for each crop type both the irrigation amount (Idose) and the soil moisture threshold (SMthreshold) at which irrigation is triggered. To do this, a particle filter method is implemented, with particles reset each month to provide time-varying SMthreshold and Idose. In a second step, the retrieved SMthreshold and Idose values are used as input to SAMIR to estimate the weekly irrigation and its uncertainty. The assimilation approach (SSM-ASSIM) is tested over the 8000 hectare Algerri-Balaguer irrigation district located in northeastern Spain, where in situ irrigation data integrating the whole district are available at the weekly scale during 2019. For evaluation, the performance of SSM-ASSIM is compared with that of the default FAO-56 irrigation module (called FAO56-DEF), which sets the SMthreshold to the critical soil moisture value and systematically fills the soil reservoir for each irrigation event. In 2019, with an observed annual irrigation of 687 mm, SSM-ASSIM (FAO56-DEF) shows a root mean square deviation between retrieved and in situ irrigation of 6.7 (8.8) mm week-1, a bias of +0.3 (−1.4) mm week-1, and a Pearson correlation coefficient of 0.88 (0.78). The SSM-ASSIM approach shows great potential for retrieving the weekly water use over extended areas for any irrigation regime, including over-irrigation. •High resolution Sentinel-1-derived soil moisture is used to quantify irrigation.•Soil moisture is assimilated in a FAO-56 water balance model at field scale.•Irrigation dynamics are well retrieved at the irrigation district and plot scales.•The proposed approach outperforms the standard FAO-56 irrigation module.•The approach can simulate over-irrigation (relative to simulated optimal crop water needs).