0000000000848918

AUTHOR

Andrew F. Feldman

showing 3 related works from this author

Global L-band vegetation volume fraction estimates for modeling vegetation optical depth

2021

The attenuation of microwave emissions through the canopy is quantified by the vegetation optical depth (VOD), which is related to the amount of water, the biomass and the structure of vegetation. To provide microwave-derived plant water estimates, one must account for biomass/structure contributions in order to extract the water component from the VOD. This study uses Aquarius scatterometer data to build an L-band global seasonality of vegetation volume fraction (d), representative of biomass/structure dynamics. The dynamic range of d is adapted for its application in a gravimetric moisture (Mg) retrieval model. Results show that d ranging from 0 to 3.35.10- 4 is needed for modelling physi…

CanopyBiomass (ecology)RadarTeledeteccióbiomassMoisturePhenologyAttenuationvegetation gravimetric moisture contentSeasonality:Enginyeria de la telecomunicació [Àrees temàtiques de la UPC]Remote sensingmedicine.diseaseAtmospheric sciencesVegetation gravimetric moisture contentAquarius scatterometerVegetation structuremedicineSpatial ecologyEnvironmental scienceBiomassmedicine.symptomVegetation (pathology)
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Time-variations of zeroth-order vegetation absorption and scattering at L-band

2021

Abstract Surface soil moisture and vegetation optical depth (VOD), as an indicator of vegetation wet biomass, from passive microwave remote sensing have been increasingly applied in global ecology and climate research. Both soil moisture and VOD are retrieved from satellite brightness temperature measurements assuming a zeroth order radiative transfer model, commonly known as the tau-omega model. In this model the emission of a vegetated surface is dependent on soil moisture, vegetation absorption and vegetation scattering. Vegetation scattering is normally represented by the single scattering albedo, ω, and is commonly assumed to be a time-invariant calibration parameter to achieve high ac…

LidarScatteringSingle-scattering albedoAttenuationeffective scattering albedoSoil ScienceGeologySoil scienceContext (language use)SMAPradiometryVegetationvegetation optical depthICESat-2L-bandAtmospheric radiative transfer codesBrightness temperaturerelative canopy scatteringEnvironmental scienceComputers in Earth SciencesAbsorption (electromagnetic radiation)relative canopy absorptionRemote sensingRemote Sensing of Environment
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Retrieval of Forest Water Potential from L-Band Vegetation Optical Depth

2021

A retrieval methodology for forest water potential from ground-based L-band radiometry is proposed. It contains the estimation of the gravimetric and the relative water content of a forest stand and tests in situ- and model-based functions to transform these estimates into forest water potential. The retrieval is based on vegetation optical depth data from a tower-based experiment of the SMAPVEX 19–21 campaign for the period from April to October 2019 at Harvard Forest, MA, USA. In addition, comparison and validation with in situ measurements on leaf and xylem water potential as well as on leaf wetness and complex permittivity are foreseen to understand limitations and potentials of the pro…

L bandRadiometerXylemradiometryVegetationL-bandFootprintharvard forestforestvegetation moistureEnvironmental scienceRadiometryVegetation optical depthground-basedwater potentialWater contentLeaf wetnessRemote sensing2021 IEEE International Geoscience and Remote Sensing Symposium IGARSS
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