Figure 10: The extracted road network presented in CAD-based
environment
In order to evaluate the obtained results, the road network
available in the test area was manually extracted to produce a
road network reference map, which is shown in Figure 11.
The comparison between Figures 10 and 11 showed that
wherever a road pixel is extracted by the automatic procedure,
its geometric position is exactly the same as manually produced
road network, but the completeness of extracted road network is
with doubt. Figure 12 shows those areas where the designed
automatic procedure failed to detect road pixels, which are
presented in boxes.
4. CONCLUSIONS AND RECOMMENDATIONS
Image processing techniques such as pattern recognition and
object detection algorithms do not provide fully structured data
for GIS environments. This is mainly due to the fact that the
results of image processing algorithms are raster maps while
GIS environments need structured vector based data as their
input entities. Furthermore, it should be noticed that CAD based
facilities could not be performed directly on source imaged
because of the complicated nature of them, especially when
dealing with high resolution ones.
Therefore, the combination of image processing techniques and
CAD facilities can be a good alternative to automate the process
of data preparation and entering into GIS.
A new approach was designed and implemented in this research,
and a fully automatic procedure was designed and implemented
to extract road centerlines from high resolution satellite images.
Neural networks and digital image processing algorithms such
as morphological operators were used to extract road centerline
from satellite images and present it as an edited road raster map.
Then obtained raster map was prepared and vectorized using the
facilities provided by CAD-based environments. The final
result is the structured vector based road network presented in
CAD environment where it can be easily transformed to GIS.
The comparison between obtained results and road network
reference map proved acceptable geometric accuracy of
designed procedure.
The designed and implemented method in this research for
automatic road extraction was mainly based on spectral and
geometric properties of road networks. Knowledge-based road
extraction methods, which are based on an appropriate road
model, could be an efficient method for further study. In these
methods, even when some parts of the road in input source
image, road raster map or thinned road center line are missed,
they could be recovered based on the road knowledge injected
into the system via knowledge-based road model.
REFERENCES
GRUEN, A., AGOURIS, P, LI, H„ 1995. Linear Feature
Extraction with Dynamic Programming and Globally Enforced
Least Squares Matching. In: Gruen, A., Kuebler, O., Aqouris, P.
(Eds.), Automatic Extraction of Man-Made Objects from Aerial
and Space Images. Brikhauser, Basel. 83-94.
GRUEN, A., LI, H., 1997. Semi-Automatic Linear Feature
Extraction by Dynamic Programming and LSB-Snakes.
Photogrammetric Engineering and Remote Sensing. 63(8):
985-995.
HARALICK, ROBERT M., AND LINDA G. SHAPIRO. 1992.
Computer and Robot Vision. Volume I. Addison-Wesley, pp.
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