Vertical Structure of P-Band Temporal Decorrelation at the Paracou Forest: Results From TropiScat

Vertical Structure of P-Band Temporal Decorrelation at the Paracou Forest: Results From TropiScat

In this letter, we present the results from the ground-based European Space Agency campaign TropiScat, which is aimed at evaluating the temporal coherence at P-band in a tropical forest in all polarizations and at different heights within the vegetation layers. The TropiScat equipment has been opera...

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Bibliographic Details
Published in:IEEE geoscience and remote sensing letters Vol. 11; no. 8; pp. 1438 - 1442
Main Authors: Dinh Ho Tong Minh, Tebaldini, Stefano, Rocca, Fabio, Thuy Le Toan, Borderies, Pierre, Koleck, Thierry, Albinet, Clement, Hamadi, Alia, Villard, Ludovic
Format: Journal Article
Language:English
Published: Piscataway IEEE 01-08-2014
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Arrays
Biomass
Biomass Monitoring Mission for Carbon Assessment (BIOMASS)
Coherence
coherence matrix
Decorrelation
forest vertical structure
P-band tomography
Remote sensing
Synthetic aperture radar
temporal decorrelation
Tomography
TropiScat
Biomass Monitoring Mission for Carbon Assessment (BIOMASS)
P-band tomography
coherence matrix
forest vertical structure
TropiScat
temporal decorrelation
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Summary:In this letter, we present the results from the ground-based European Space Agency campaign TropiScat, which is aimed at evaluating the temporal coherence at P-band in a tropical forest in all polarizations and at different heights within the vegetation layers. The TropiScat equipment has been operated since October 2011 at the Paracou field station, French Guiana, to continuously produce height-range images of the forest with a temporal sampling of 15 min. The forest temporal behavior can be then captured by analyzing the interferometric coherence between the images gathered at different times, considering time scales on the order of hours, days, and months. The results indicate that the vegetation is likely to undergo a significant motion during day hours due to wind and temperature changes, whereas it appears to be definitively more stable during night hours. This result appears to provide a very useful input to the Biomass Monitoring Mission for Carbon Assessment (BIOMASS), as it suggests that the performance over a tropical forest could be optimized by gathering acquisitions in early morning or night hours. The long-term temporal decorrelation has been then evaluated by considering dawn-dawn acquisitions to minimize the impact of wind gusts and by excluding rainy days in order to not confuse forest and system decorrelation. As a result, the temporal coherence at the ground level was found to stay high at about 0.8 at 27 days, whereas the temporal coherence at the canopy height was found to be about 0.8 at 4 days and about 0.65 at 27 days, indicating coherence sensitivity to height.
ISSN:1545-598X
1558-0571
DOI:10.1109/LGRS.2013.2295165