Author | dc.contributor.author | Sobrino, J. A. | |
Author | dc.contributor.author | Jiménez Muñoz, J. C. | es_CL |
Author | dc.contributor.author | Sòria, G. | es_CL |
Author | dc.contributor.author | Gómez, M. | es_CL |
Author | dc.contributor.author | Barella Ortiz, A. | es_CL |
Author | dc.contributor.author | Romaguera, M. | es_CL |
Author | dc.contributor.author | Zaragoza, M. | es_CL |
Author | dc.contributor.author | Julien, Y. | es_CL |
Author | dc.contributor.author | Cuenca, J. | es_CL |
Author | dc.contributor.author | Atitar, M. | es_CL |
Author | dc.contributor.author | Hidalgo, V. | es_CL |
Author | dc.contributor.author | Franch, B. | es_CL |
Author | dc.contributor.author | Mattar, C. | es_CL |
Author | dc.contributor.author | Ruescas, A. | es_CL |
Author | dc.contributor.author | Morales Salinas, Luis | es_CL |
Author | dc.contributor.author | Gillespie, A. | es_CL |
Author | dc.contributor.author | Balick, L. | es_CL |
Author | dc.contributor.author | Su, Z. | es_CL |
Author | dc.contributor.author | Nerry, F. | es_CL |
Author | dc.contributor.author | Peres, L. | es_CL |
Author | dc.contributor.author | Libonati, R. | es_CL |
Admission date | dc.date.accessioned | 2010-05-10T18:49:07Z | |
Available date | dc.date.available | 2010-05-10T18:49:07Z | |
Publication date | dc.date.issued | 2008-09 | |
Cita de ítem | dc.identifier.citation | International Journal of Remote Sensing Vol. 29, Nos. 17–18, September 2008, 4961–4991 | en_US |
Identifier | dc.identifier.issn | 0143-1161 print | |
Identifier | dc.identifier.other | DOI: 10.1080/01431160802036516 | |
Identifier | dc.identifier.uri | https://repositorio.uchile.cl/handle/2250/120161 | |
Abstract | dc.description.abstract | A description of thermal radiometric field measurements carried out in the
framework of the European project SENtinel-2 and Fluorescence Experiment
(SEN2FLEX) is presented. The field campaign was developed in the region of
Barrax (Spain) during June and July 2005. The purpose of the thermal
measurements was to retrieve biogeophysical parameters such as land surface
emissivity (LSE) and temperature (LST) to validate airborne-based methodologies
and to characterize different surfaces. Thermal measurements were carried
out using two multiband field radiometers and several broadband field
radiometers, pointing at different targets. High-resolution images acquired with
the Airborne Hyperspectral Scanner (AHS) sensor were used to retrieve LST and
LSE, applying the Temperature and Emissivity Separation (TES) algorithm as
well as single-channel (SC) and two-channel (TC) methods. To this purpose, 10
AHS thermal infrared (TIR) bands (8–13 mm) were considered. LST and LSE
estimations derived from AHS data were used to obtain heat fluxes and
evapotranspiration (ET) as an application of thermal remote sensing in the
context of agriculture and water management. To this end, an energy balance
equation was solved using the evaporative fraction concept involved in the
Simplified Surface Energy Balance Index (S-SEBI) model. The test of the
different algorithms and methods against ground-based measurements showed root mean square errors (RMSE) lower than 1.8K for temperature and lower
than 1.1 mm/day for daily ET. | en_US |
Lenguage | dc.language.iso | en | en_US |
Publisher | dc.publisher | Taylor & Francis | en_US |
Título | dc.title | Thermal remote sensing in the framework of the SEN2FLEX project: field measurements, airborne data and applications | en_US |
Document type | dc.type | Artículo de revista | |