Full text: Proceedings, XXth congress (Part 2)

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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
fragmented, broken parallel lines. Aiming at this, a new 
algorithm called profile-tracing algorithm is presented. The 
principle of the new algorithm consists of two steps: 
eo  Firstly group these lines for creating possible 
candidate road segments according to profiles; 
e Detect changes of road and extract road sides 
according to the candidate road segments. 
For the first step, the main strategy is to select reliable parallel 
lines as searching start lines, and make profiles at their two 
vertexes so as to find possible conjoint parallel lines. Then link 
these parallel lines into one long line and repeat this procedure 
until all the given conditions can't be satisfied. For the second 
step, the key problem is whether roadsides can be extracted and 
how to trace roadsides according to the existence information. 
For every road segment, maybe it doesn't overlay the whole 
length of actual road. However, for many road segments, they 
can supplement each other and form a new line whose length is 
close to the whole road length. Base on these lines, roadsides 
can be created with the help of other grouping lines. The road 
length and width can be defined with the help of GIS 
information. 
4.3 Astrategy for extracting road networks from images 
Structure features are main representation information of 
images. Almost all road extraction algorithms employ structure 
information. However, when there exist strong noise, low 
contrast and other factors in images, the extraction results using 
the algorithms based on structure features are often not well. 
Under this situation using statistical information is a good 
supplement. But how to define a statistical model and utilize the 
statistical parameters are key problems. Obviously from the 
viewpoint of extraction strategy, the hybrid extraction strategy 
based on structure information and statistical information is the 
best choice. 
Generally, a lot of statistical models are very complex and there 
are many unknown parameters to be defined. So the algorithms 
based on these statistical models are not practical. A simple and 
practical statistical model is necessary. In general, local road 
segments in images have better statistical properties. Suppose 
we overlay a window with a given window size on the road in 
images, the local statistical properties of roads can be reflected 
from the properties of the gray histogram, gray gradient 
histogram, gray gradient intensity histogram in the window. So 
these three parameters can be used as statistical parameters. 
Candidate road segments can be found if the statistical 
properties in this window satisfy the following three conditions: 
e The grey histogram in the window has only one peak 
eo The gradient direction histogram in the window has 
two symmetric peaks 
eo The gradient intensity histogram in the window has 
one no-zero peak 
According to the above statistical properties of road segments, 
the authors design a new road-tracing algorithm based on the 
adaptive template (Su1,2002). 
Considering the limitation of traditional Snake [Kass et al.,1988] 
model for processing the road with lager road width, the authors 
employ the Ribbon-Snake model for extracting the road 
features. To avoid slow convergence properties and high 
sensitivity to initial position of traditional Snake Model, five 
kinds of condition. including continuity, curvature, image 
features, shape, range are involved in this model. The continuity 
and curvature conditions are the same definition with the Snake 
463 
model. The image features consider not only the gradient 
parameter but also the texture information. The least squares 
algorithm is employed for the shape constraint model. The 
range condition mainly control the selection of initial position 
in images. Here we use the buffer created by traced road central 
lines and road width as the searching and restriction range. 
4.4 Automatic road recognition based on knowledge base 
Automatic road recognition is a necessary task for extracting 
road networks. After many years of research, people realized 
that it is impossible to design a common algorithm for 
recognizing road networks from all kinds of images and it is 
also not enough to only depend on image information for 
automatic recognition and extraction. After great efforts of 
many years, many researchers have waked up to successful 
extracting of road networks should recur to the knowledge. In 
this paper, the authors built a road recognition expert system. 
All the knowledge is put into the knowledge base. 
Generally three obstacles hold back automatic recognition: One 
is how to acquire recognition knowledge, another is that how to 
represent knowledge quantitatively and the third is how to use 
knowledge for reasoning and recognizing road. In this 
framework we first define a basic model for road. Main 
parameters including grey value, grey variance, the length, 
width, curvature are involved in the road model. The fuzzy 
theory is employed for representing road models. According to 
different parameters we define a series of different fuzzy 
functions for road model. And a road recognition expert system 
is built. All kinds of road recognition knowledge are all put in 
the knowledge base. We use fuzzy production rules for 
representing road knowledge and uncertain reasoning models 
for road knowledge reasoning. All the recognition results are 
represented as belief values. The road segments whose belief 
value is greater than the given threshold are extracted as road. 
4.5 Re-grouping road based on global information and 
creation of new road 
After automatic road recognition the whole framework of road 
network is built and the hidden semantic contradiction is solved. 
However, the work of road extraction is not finished. The road 
network is still incomplete because of the following reasons: the 
big road gaps caused by rows of trees and buildings, the wrong 
link among road segments, the missing road caused by wrong 
recognition and other factors. So it is necessary to further 
extract and link road network. The principle and the strategy are 
to use the extracted road segments and the global information of 
road network for guiding road extraction. On one hand, the 
existent road can be used as the start point for searching and 
linking road segments; on the other hand, different road 
segments can be linked according to some rules like distance, 
grey value etc. Obviously road re-grouping is not blindfold 
when high-level information feed back to middle-level or/and 
low level processing. 
Under the guidance of global topological information, the road 
grouping and linking the iterative procedures until the last road 
networks are created. The authors think four parts should be 
processed in this procedure: road re-grouping, creation of road 
crossings, creation of road branches, iterative road extraction. 
Some extraction results based on the whole framework in this 
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