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Figure | Overview of applied methods
Approach 1 Supervised classification (standard)
In this approach, a standard procedure of image
processing, a type of supervised classification was used
(Richards, 1993). Supervised classification is the process
of using samples of known identity to classify pixels of
unknown identity. For this process training fields are
selected in different land cover classes. We used the
generally applied maximum likelihood classification,
since it uses algorithms in a statistically acceptable
manner and is based on probability statistics.
For evaluation of the classification accuracy an error
matrix was calculated based on the independent geo-
dataset. The classification was summarized in a
classification accuracy report presenting overall accuracy,
producers accuracy and users accuracy of the different
land cover classes. These accuracy measures are defined
as follows:
e Overall accuracy = Z correct pixels/ Z Pixels in error
matrix
e Producer's accuracy - X correct pixels per category/ X
reference pixels
e. User's accuracy — X correct pixels per category/ X
classified pixels
This error matrix is used to compare this relatively
straightforward classification with error matrices
produced by the other approaches using ancillary
information. All image processing has been performed
with Erdas Imagine.
Approach 2 Topographic normalization before
supervised classification
In this approach the data were topographically normalized
before classification. This normalization is meant to
overcome the problem that slopes facing the sun are
lighter than slopes without sun.
A number of investigations which attempt to explain the
topographic effect, especially for Landsat and Spot digital
multispectral data, have been conducted. Most of these
studies attempted to account for and correct the negative
aspects associated with the topographic effect by
modifying the surface radiance values recorded by the
satellite sensors using the cosine of the angle of incidence
and inclination, as calculated from a registered digital
elevation data set. The topographic effect in digital
imagery can be compensated for by transformation based
on Lambertian or Non-Lambertian reflectance models. In
this study both models are used.
The Lambertian Reflectance model assumes that the
surface reflects incident solar energy uniformly in all
directions, and that variations in reflectance are due to the
amount of incident radiation, which lead to simple
formulas.
The Non-Lambertian Reflectance model (Minaert 1961)
supposes that the observed surface does not reflect
incident solar energy uniformly in all directions. The data
were transformed using equations developed by Colby
(1991). The Minnaert constant (k), needed in the
equations was found by regressing a set of observed
brightness values from the remotely sensed imagery with
known slope and aspect values, with the same type of
land cover. On both normalized images again supervised
classifications are performed and the accuracy is
evaluated using error matrices and accuracy reports.
Approach 3 Contextual information to improve
supervised classification.
Ancillary data can be incorporated in image classification
during :
1. Pre - classification scene stratification.
2. Post - classification class sorting and
3. Classification modification through prior probabilities
(Hutchinson, 1982).
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 343
