In the study area a random sample consisting of
1454 pixels yields
là | [0.647 0.265 0.364 0.096 0.183 0.310 |
fa 0.052 0.122 0.068 0.04 0.083 0.092
ps | _ | 0.162 0.132 0.296 0.079 0.117 0.117
pa | | | 0.07 0.291 0.148 0.581 0.383 0.315
bs 0.011 0.032 0.04 0.119 0.150 0.075
[js | | 0.059 0.159 0.085 0.083 0.083 0.092 |
| 0.1940 |
0.1467
0.1229
0.1838 (5)
0.0419
| 0.3110.
and the estimated proportions are
Far here] 042206 |
f» 0.07340
p - | | _ | 01401
b. 0.3181
fs 0.0614
| ps | | 0.0003 |
The estimates deviate from the true proportions
known from the field survey only by a small margin.
The reason for is the large size of the sample and samp-
ling with the sampling unit pixel. But, the coefficient
of reliability K is very low. In case of ML classification
of the raw SAR data both classifiers are not correlated.
The sampling accuracy depends almost entirely on the
true classifications. As K approaches 0 the variance
depends only on the size of the sample n (Equation 7).
If K rises, the left term of Equation 7 becomes smal-
ler with (1 — K). But the right term must be added.
This term is, however, very small because of large N.
Thus, some expensive true observations are replaced
by a large number of misclassified observations.
Larger K values are found in the results of the ma-
Jority filtering. In that case the results of the ML clas-
sification of the entire imagery improve the accuracy
of the estimates from the small sample with true clas-
sifications. But the majority filtering rises the entire
cost of the sampling.
In the sampling scheme described above a full image
classification was used. The full frame classification
can be replaced by a sample with N pixels, where N >>
n. In that case the n members of the sample are called
subsample. With a given coefficient of reliability K
and the probability of misclassification 0, both n and
International Archives of Photogrammetry and
N can be optimized for given accuracy requirements
Tenebein (1972) describes the procedure.
3. CONCLUSIONS
From the results of this study can be concluded,
that the double sampling has the capability to cor.
rect misclassification errors of the ML classification,
However, the coefficient of reliability is with ERS.1.
SAR-data very low. This means that a comparatively
large and expensive sample with true classifications is
needed to get sufficient accurate estimates of the e.
ror probability matrix and other parameters. The re.
sults apply to the sampling unit pixel. The sampling
performance can be improved by a carefully trained
classifier, use of systematical sampling and exclusion
of non-agricultural areas from the sampling.
The author thanks ESA for providing the ERS-1 SAR
imagery
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Remote Sensing. Vol. XXXI, Part B7. Vienna 1996
