Angular Reflectance of Leaves With a Dual-Wavelength Terrestrial Lidar and Its Implications for Leaf-Bark Separation and Leaf Moisture Estimation

A new generation of multiwavelength lidars offers the potential to measure the structure and biochemistry of vegetation simultaneously, using range resolved spectral indices to overcome the confounding effects in passive optical measurements. However, the reflectance of leaves depends on the angle o...

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Bibliographic Details
Published inIEEE transactions on geoscience and remote sensing Vol. 55; no. 6; pp. 3084 - 3090
Main Authors Hancock, Steven, Gaulton, Rachel, Danson, F. Mark
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Bark
Canopies
Dependence
Incidence angle
Laser radar
Lasers
Leaf angle
Leaves
Lidar
Measurement by laser beam
Moisture
Optical measurement
Plant cover
Reflectance
remote sensing
Scattering
Separation
Surface emitting lasers
technology assessment
Terrestrial environments
Trigonometric functions
Vegetation
Vegetation mapping
Wavelength
Wavelength measurement
Wavelengths
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Summary:A new generation of multiwavelength lidars offers the potential to measure the structure and biochemistry of vegetation simultaneously, using range resolved spectral indices to overcome the confounding effects in passive optical measurements. However, the reflectance of leaves depends on the angle of incidence, and if this dependence varies between wavelengths, the resulting spectral indices will also vary with the angle of incidence, complicating their use in separating structural and biochemical effects in vegetation canopies. The Salford Advanced Laser Canopy Analyser (SALCA) dual-wavelength terrestrial laser scanner was used to measure the angular dependence of reflectance for a range of leaves at the wavelengths used by the new generation of multiwavelength lidars, 1063 and 1545 nm, as used by SALCA, DWEL, and the Optech Titan. The influence of the angle of incidence on the normalized difference index (NDI) of these wavelengths was also assessed. The reflectance at both wavelengths depended on the angle of incidence and could be well modelled as a cosine. The change in the NDI with the leaf angle of incidence was small compared with the observed difference in the NDI between fresh and dry leaves and between leaf and bark. Therefore, it is concluded that angular effects will not significantly impact leaf moisture retrievals or prevent leaf/bark separation for the wavelengths used in the new generation of 1063- and 1545-nm multiwavelength lidars.
ISSN:0196-2892
1558-0644
DOI:10.1109/TGRS.2017.2652140