The non-Lambertian directional reflectance of a multilayer vegetative canopy is derived. Cause of the reflectance of the canopy is made traceable to the properties of the biological elements of the canopy. A new and possibly useful canopy property leading to the down sun "hot spot" is discussed.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/33735/1/0000249.pd
Two radiative transfer canopy models, SAIL and the two-layer Markov-Chain Canopy Reflectance Model (...
Two Fagus sylvatica L. stands with different Leaf Area Index and similar planophile Leaf Angle Distr...
Illuminating any reflective rough or structured surface by a directional light source results in an ...
The non-Lambertian directional reflectance of a multilayer vegetative canopy is derived. Cause of th...
The variation of the directional reflectance of a vegetative canopy with azimuthal view angle become...
The purpose of this study was to isolate factors contributing to the formation of the hot spot featu...
219-228Vegetative surfaces are non-lambertian and deriving their spectral properties from space-born...
The recent work of Allen, Gayle, and Richardson (1970) and Suits (1972) has been extended to compute...
Spectral hemispherical-conical reflectances of a nadir looking sensor were taken throughout the day ...
Bracken presents a serious environmental problem in many regions of the world and remote sensing off...
Abstract—The combined PROSPECT leaf optical properties model and SAIL canopy bidirectional reflectan...
Considerable variations have been noted in the relationship between remotely sensed data and canopy ...
A computationally efficient reflectance model for row planted canopies is developed in this paper th...
Various technical issues related to mapping of vegetative type, condition and stage of maturity, uti...
Interpreting remotely-sensed data requires realistic, but simple, models of radiative transfer that ...
Two radiative transfer canopy models, SAIL and the two-layer Markov-Chain Canopy Reflectance Model (...
Two Fagus sylvatica L. stands with different Leaf Area Index and similar planophile Leaf Angle Distr...
Illuminating any reflective rough or structured surface by a directional light source results in an ...
The non-Lambertian directional reflectance of a multilayer vegetative canopy is derived. Cause of th...
The variation of the directional reflectance of a vegetative canopy with azimuthal view angle become...
The purpose of this study was to isolate factors contributing to the formation of the hot spot featu...
219-228Vegetative surfaces are non-lambertian and deriving their spectral properties from space-born...
The recent work of Allen, Gayle, and Richardson (1970) and Suits (1972) has been extended to compute...
Spectral hemispherical-conical reflectances of a nadir looking sensor were taken throughout the day ...
Bracken presents a serious environmental problem in many regions of the world and remote sensing off...
Abstract—The combined PROSPECT leaf optical properties model and SAIL canopy bidirectional reflectan...
Considerable variations have been noted in the relationship between remotely sensed data and canopy ...
A computationally efficient reflectance model for row planted canopies is developed in this paper th...
Various technical issues related to mapping of vegetative type, condition and stage of maturity, uti...
Interpreting remotely-sensed data requires realistic, but simple, models of radiative transfer that ...
Two radiative transfer canopy models, SAIL and the two-layer Markov-Chain Canopy Reflectance Model (...
Two Fagus sylvatica L. stands with different Leaf Area Index and similar planophile Leaf Angle Distr...
Illuminating any reflective rough or structured surface by a directional light source results in an ...
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