v are
leasured
bution of
ed under
on of the
imuth 180
sured one
oot Mean
fective for
ince.
e in wide
directional
ce canopy
5 15 deg.
ssults are
be higher
vs that the
directional
t of leaf
jaring the
21th, the
ction, and
eg. zenith
J. azimuth
ference of
a) Dense plot, V.A.=4.
sh
e
©
80
60
40
20
0
100,2
807
60
40
20
Sparse plot, V.A.=4.5deg.
Calculated reflectance factor (%)
Back scattering
c) Dense plot, V.A.=85.5d
18\7/21
(d) Sparse plot, V.A=85.5deg.
0 |
-90-60-30 0 30 60 9090-60-30 O 30 60 90
Forward scattering
View zenith (deg.)
Fig. 5. Bidirectional reflectance characteristics obtained by the simulation (condition B-1)
Therefore, relation between leaf average
inclination and R(45° )/R(0° ) is analyzed. Where R(¢)
is the reflectance factor to view zenith angle ¢,
azimuth angle 180° . Without earlier growth stages
(without data of sparse plot in june 9th and june 16th),
the two parameters are adequately correlated. The
correlation coefficient is 0.84.
5. CONCLUSION
NIR bidirectional
distributions of thirteen kinds of rice canopies are
simulated using the 3-D monte carlo method and
measured in an experimental field. The simulation is
carried out under two different field conditions. One is
similar to the condition of the experimental field and the
other is the wide spread field condition under the
parallel solar beam. The simulated reflectance factors
under the former condition fit the measured one well.
As the result of the simulation, the ratio of the
reflectance factors (view zenith: 45deg. to 0 deg. ) from
wide spread field is suggested to give average
inclination of rice canopy.
In consequence of this research, bidirectional
reflectance characteristics of rice canopy should be
analyzed using this model under some kinds of physical
conditions.
In this paper, reflectance
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International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996
