IMPROVED CLASSIFICATION OF SPOT MULTI-SPECTRAL IMAGES
FOR LAND-COVER TYPES EVALUATION ASSISTED BY
DIGITAL ELEVATION MODEL (DEM) AND AERIAL PHOTOGRAPHS,
A CASE STUDY
Saeid Noori Bushehri and Nooshin Khorsandian
Department of GIS, Department of Photogrammetry,
Assistant Director of GIS Dept., Remote Sensing Specialist
National Cartographic Center (N.C.C)
Tehran, Iran
Commission VII, Working Group 2
KEY WORDS: Remote Sensing, L.and-Use, Classification, Image, SPOT, Multispectral, Spectral.
ABSTRACT:
The SPOT scene available for field work site, annually used by PHM3 & CAR3 students of ITC, was classified. The
classified part is our area of interest for improved classification, whose existing classified map has been used as the
ground truth. In conjunction with this, topographic data has been collected from mosaicked orthophotos which are
subsequently digitized and overlaid to the composite SPOT image. The so formed topographic network superimposed
to the landuse parcels visible on the satellite images is basically our tool for classification improvement as per case
study title.
Assessment carried out to compare and contrast the conventional against improved classifications depicts that there is
a great role played by introduction of both mosaicked orthophoto from scanned aerial photo imageries and DEM
since the area in question is mountainous and of various landuse.
1. INTRODUCTION
The great advantage of having data available digitally is
that it can be processed by computer either for machine
assisted information extraction or for embellishment
before an image product is formed. Remotely sensed
image data of the earth's surface acquired from either
aircraft or spacecraft platforms is readily available in
digital format; specially the data is composed of discrete
picture elements or pixels and radiometrically it is
quantized into discrete brightness levels. Even data that
is not recorded in digital form initially can be converted
into discrete data by use of digitizing equipment such as
scanners.
One of the applications of remotely sensed digital data,
specially satellite imagery, is using them in /and cover
classification. There is two methods. namely photo
interpretation and quantitative analysis. Photo
interpretation is done by expenenced operators to
identify ground features and overall land cover.
Successful interpretation needs high quality images and
expert operators. Since there is a need of supervision of
human, it is too difficult and/or impractical to work in
pixel level. We have to use computer to evaluate the
satellite imagery with several bands in pixel level and
with high radiometric resolution for accurate results of
analysing. Computer assisted interpretation of remotely
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sensed data is called quantitative analysis. In this
method, at first land cover types or spectral classes ate
defined by the operators (users of the images), then by
using of ground truth (data collected at the feld
operations) sample land cover types are identified in
limited parts of images. In fact, we try to teach the
computer the nature of different land cover types and
their spectral specifications (training). In the next step,
the trained computer starts to identify land cover types
in the rest of images, namely a label is assigned to each
pixel due to its spectral value. This kind of classification
is called c/assic or conventional classification.
Present article is the result of a case study of authors at
the end of a course, "Integrated Mapping and
Geoinformation Production 3 (IGP3)," in 1993 at ITC,
The Netherlands. The aim of the case study was to
improve the conventional classification method by use
of scanned aerial photos and existing DEM (Digital
Elevation Model) of area.
Geometric distortions in satellite images can be related
to number of factors, including
(1) the rotation of the earth during image
acquisition,
(ii) the wide field of view of some sensors,
(iii) the curvature of the earth,
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996
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