Title:	Cloud-based fusion of Sentinel-1 Radar, MODIS and soil moisture data for resolution-refined evapotranspiration mapping in mountain coffee systems.
Authors:	KLINKE NETO, G. OLIVEIRA, A. H. BOLFE, E. L. BERGIER, I. GOULART, A. J. H.
Affiliation:	GUSTAVO KLINKE NETO, UNIVERSIDADE ESTADUAL DE CAMPINAS; ANNA HOFFMANN OLIVEIRA, UNIVERSIDADE FEDERAL DE SÃO CARLOS; EDSON LUIS BOLFE, CNPTIA; IVAN BERGIER TAVARES DE LIMA, CNPTIA; ANTONIO JOSÉ HOMSI GOULART, UNIVERSIDADE DE SÃO PAULO.
Date Issued:	2026
Citation:	Sustainability, v. 18, n. 13, 6473, July 2026.
Description:	Accurate monitoring of hydrological dynamics in complex perennial landscapes is a cornerstone for tropical agricultural sustainability. Traditional energy balance models based on orbital optical data often face methodological bottlenecks due to cloud cover and the “greening myth,” where optical indices fail to capture immediate water stress due to the non-linear decoupling between stomatal closure and pigment loss. This study developed a cloud-integrated multisensor framework to estimate actual evapotranspiration (ETa) at a refined 100 m resolution in mountain coffee systems, utilizing active microwave proxies from Sentinel-1. We fused polarimetric metrics—Degree of Polarization (DoP) and Shannon Entropy (SE)—with land surface temperature and soil moisture data. Multiple Linear Regression (MLR) was compared against non-linear algorithms (Random Forest and SVR) to prioritize model parsimony and physical interpretability. The results show that MLR emerged as the most parsimonious and suitable model within this localized dataset scope (R2 = 0.872; RMSE = 2.916 mm/8-day), outperforming complex “black-box” architectures. Soil moisture emerged as the dominant environmental driver of ETa variability, while SAR-based metrics served as sensitive mechanical proxies for canopy geometric heterogeneity and macro-structural variations. Cross-correlation analysis revealed a 16-day lag, empirically indicating that biophysical water shifts temporally precede geometric canopy alterations. Operationally, this framework ensures temporal continuity under persistent cloud cover and provides high-fidelity spatial detailing for precision water management. This approach offers an auditable and scalable tool for watershed planning and climate resilience in tropical agriculture.
Thesagro:	Evapotranspiração Umidade do Solo
Keywords:	Fusão de dados Índice polarimétrico Sustentabilidade Micro-ondas ativos Café de montanha Active microwaves Data fusion Google Earth Engine Polarimetric indices Sustainability
ISSN:	2071-1050
DOI:	https://doi.org/10.3390/su18136473
Type of Material:	Artigo de periódico
Access:	openAccess
Appears in Collections:	Artigo em periódico indexado (CNPTIA)