of altitude z, slope s and shaded relief Sy44 of these pixels are
170~290m, 12°~41° and 0.0~0.9 respectively. Owing to the
topographic effect, the digital counts of the hardwood canopy
varies from 34~40, 29~36 and 24~66 in XS1, XS2 and XS3
bands respectively (Fig. 2). That such large variation of sensor
response of a given canopy , especially in XS3 band, is the main
reason to hamper the application of satellite image over
mountainous terrain. The retrieved sea-level aerosol optical
depth z,, (underline) are 0.46, 0.37, 0.44 and linear decay rate
c, are 0.091, 0.071, 0.001 in XS1-XS3 bands respectively
(Table 1). Mean hardwood reflectances 4 are 0.026, 0.023 and
0.206 respectively in XSI-XS3 bands respectively.
Sensitivity of derived surface reflectance to aerosol optical
depth is also studied by artificially deviating the optimized z,,
to +0.1. When z,,is under-estimated 0.1, 4 is over-estimated
up to 0.049, 0.053 and 0.232 in XS1-XS3 bands respectively.
On the contrary, 4 is under-estimated to 0.186 in XS3 band and
even negative value ('fail' denoted in Table 1) in XS1 and XS2
bands respectively. When tz, is deviated, surface reflectance
at nearby shadow (S44; —0.0) is more sensitive to aersol optical
depth than that at well illuminated as shown in Fig. 3. This is
because diffuse irradiance determined from aerosol optical
depth is dominated in nearby shadow terrain. The error of
derived reflectance at shadow in rugged terrain can be up to 0.1
in XSI-XS3 bands when Az, is 0.1, whereas the error is only
about 0.01 in horizontal surface (Liu et al. 1996). Thus it
could be concluded that more accurate aerosol optical depth
should be needed in rugged terrain, if equal accuracy of surface
reflectance is required. It is also noted that the optimized zs
in XS bands don't follow Angstrom formula. z„oin XS3 band
is greater than that in XS2 band. Probably it results from: (1)
Lambertian surface assumption of the atmospheric correction
model; (2) inaccurate modeling of adjacent slope reflected
irradiance E,
The surface reflectance is derived by correcting the atmospheric
and topographic effects of the image. Table 2 shows the
difference of mean reflectance in shaded and wel-illuminated
(u,70.8) terrain before and after atmospheric correction.
Acacia is chosen to verify the result of correction and testify the
sensitivity of the algorithm to selected canopy. Typical
spectral reflectances demonstrate the effect of atmospheric
correction. In addition, difference of reflectances of pixels
located in shaded and well-illuminated areas are greately
reduced, especially in near-IR band. The reflectance
difference of acacia in shade and well-illuminated area is -0.024
in XS3 band, which is largely compared to the hardwood (-
0.001) selected to retrieve the aerosol optical depth in the robust
algorithm. Thus the algorithm is considered to be sensitive to
the selected canopy. It is again probably due to the
insufficiency of Lambertian surface assumption.
By using the atmospheric correction model with retrieved
aerosol optical depth as input, topographic effect is largely
corrected in surface reflectance image (Fig. 1b) as compared to
apparent reflectance image (Fig. la). To view the difference
between with and without correction, the same enhancement
function is applied. However, there are still some pixels
under-corrected or over-corrected both at ridge or valley and
intersection of bright-dark area. It is due to insufficiency of
DTM spatial resolution or resampling of geometric correction in
such a drastic change terrain. Landcover change may be one
of the reasons as shown in the lower-left part of Fig. 1b. This
area is over-corrected because its shaded relief (Fig. 2) is under-
estimated.
108
Classification results bewteen with and without correction are
also used to testify the algorithm. ISOCLASS clustering
algorithm (IDIMS, 1992) is applied in classification.
Uncorrected image is clustered to classes of urban, high-
reflective land, mixed bare soil and urban, and two terrain
related classes such as forest under high illumination, forest
under low illumination (Fig. 4a). These spectral classes didn't
correspond with real ground canopies very well, especially two
terrain related forest classes due to topographic effect.
However, forest, high-reflective land, bare soil, urban and grass
are fairly well clustered if one uses the surface reflectance
image to classify (Fig. 4b). The forest class includes
hardwoods, acacia and tea, because their pairwise transformed
divergences are all smaller than 1.6. The overall accuracy is
91.7%. Kappa statistics is 0.87 (Congalton 1991). One can
conclude that classification accuracy is improved if the satellite
image is corrected by the atmospheric correction model.
5. CONCLUSION
Promising reduction of topographic effect of satellite image is
achieved by using the proposed atmospheric correction model.
Aerosol optical depth retrieved in the robust algorithm is shown
to be optimized as deviated ones can produce large error in
shadow areas. In comparing the sensitivity study of the
previous study (Liu ef al. 1996), more accurate aerosol optical
depth is needed to determine the surface reflectance in rugged
terrain than in flat terrain. Classification accuracy is also
improved by the corrected image.
Although the results are rather encouraging, more studies
should be undertaken:
(1) verification of the aerosol optical depth by field
measurement, and possible testify the model of adjacent slope
reflected irradiance;
(2) extension of the atmospheric correction model with non-
Lambertian surface;
(3) with DTM spatial resolution comparable to satellite image
(Conese et al. 1993b), and possible with apparent DTM
considering the tree-top of the terrain ( Liu 1995, Chen and Rau
1993). This work is undertaken by the authors.
REFERENCES
Chen A.J. and JY. Chen, 1991, Using Lowtran6 and DEM to
derive surface reflectance factor from SPOT HRV data.
IGARSS'91.June3-6.Espoo, Finland,pp.651-654.
Chen L.C. and J.Y. Rau, 1993, A unified solution for digital
terrain model and orthoimage generation from SPOT
stereopairs. /EEE Trans. on Geos. and Remote Sens.. vol.31,
no.6, pp1243-1252.
Civeo D.L., 1989, Topographic normalization of Landsat
thematic mapper digital imagery, Photogramm. Eng. and
Remote Sens., v55, n9, pp1303-1309.
Colby J.D., 1991. Topographic normalization in rugged terrain,
Photogramm. Eng. and Remote Sens.,v57, n5, pp531-537.
Conese C., G. Maracchi, and F. Maselli, 1993a, Improvement in
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International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996
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