Full text: Proceedings, XXth congress (Part 3)

B3. Istanbul 2004 
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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B3. Istanbul 2004 
In Figure 5 the assignment of edges is shown in green and the 
actually evaluated assignments are coloured red. 
This is easy to implement when using recursion for each step of 
the depth first search. Each recursion represents one state and 
backtracking simply needs to recover all changes made in the 
actual recursion step (this is a small number) and leaving the 
actual recursion step. 
This algorithm is useful if all possible solutions are needed. If 
the algorithm cannot find an exact matching solution it can at 
least find a largest common sub graph. 
One drawback is the missing fault tolerance of this algorithm. It 
is theoretically possible to introduce fault tolerance by allowing 
the assignment of non matching nodes, pruning of pattern graph 
branches and insertion of dummy nodes into the pattern graph. 
Each of this actions will cause the accumulation of error points 
and backtracking is done if a maximum number of error points 
is reached. But unfortunately this increases the search space 
enormously because the strong restriction of the existing classes 
and names don't apply any more and some heuristic must be 
found to prevent this large growing of the search space. 
Other possible algorithms can be build on top of this algorithm 
by using the largest common sub graph as a starting point. 
Another approach is to exploit the assumption that a sketch 
contains a lot of geometric information although the graph 
constructed from the sketch consists of topological properties. 
Some of the nodes in the graph are direct representations for 
geometric objects and can be used to produce a unique 
projection of the graph. If some of the assignments between 
pattern and reference are known the sketch can be transformed 
into the reference frame of the reference graph, producing more 
tight constraints especially for the case of inexact matching. 
This approach is strongly related to the method of elastic graph 
matching (Lee, 2002). Vital for the success is a sufficient 
similarity between sketch geometry and reference geometry and 
up to now it is not clear if this premise is true. 
4. ASET OF SKETCH CONCEPTS 
The last section was dealing with the matching process of sub 
graphs which is common for a large range of applications. But 
now some specialization to the matching of sketches is needed. 
The basic premises were already outlined in the context of the 
definition of a sketch. 
This section will propose a set of classes which has the ability 
to describe a road network with its important properties and 
leaves enough space for topological invariant operations on the 
data. Geometry is explicitly not part of the description and does 
only play a role for generating the description graph. However, 
geometry can be stored as identifiers of objects that were the 
source of the generated graph representation instances of the 
objects, which is useful for some heuristics. The principal 
geometric constraints applicable for sketches are the following: 
*  Nouniform scale across the whole sketch, but locally 
similar scale. 
=» Locally, the relations are true, e.g. a small building 
next to a big one should reflect that this relation is 
also true in reality, although the actual sizes of the 
objects cannot be used. 
* The directions drawn in the sketch, e.g. the directions 
of the roads at a junction should be approx. true. 
" The relative orientation of the objects should be 
locally true. 
    
Roads are used to explain the concepts first, at the end of this 
section an extension to other objects than roads is suggested. 
4.1 Objects 
The objects in the sketch need a representation in the 
description graph and form the skeleton for the relations 
between the objects. In a road network two main classes for 
objects can be identified if the road type is not modelled 
explicitly: roads and intersections. This choice is clear when the 
road network itself is seen as a graph where the edges are the 
roads and the nodes are the intersections. 
Here at first the nodes are considered because as 0-dimensional 
elements they are the basis for the edges. The class is called 
INTERSECTION or ISEC here. They can be easily derived 
from the geometric data. The cardinality of a node is the 
number of outgoing edges. All the points which are part of 
more than two road segments (i.e. the cardinality is greater than 
2) are intersections in the stronger sense, but points with only 
one incident road segment can also be considered as an 
intersection. They appear at the ends of roads. The cardinality 
of two should only sometimes lead to the introduction of an 
INTERSECTION because two road segments may meet at 
points where nothing special is visible and only is an artefact of 
the measurement process. Only if the direction of the road 
segments does exceed a certain limit an instance of this class 
must be modelled. 
Roads are 1-dimensional elements of the road graph and are 
always links between two intersections. Here the model class is 
called ROAD. Elements of this class are always linked with 
two terminating ISEC nodes. For reducing the number of 
classes and nodes in the graphs this is indeed a mixture between 
a relation and an object and usually should be used like in 
Figure 6. 
ISEC---ROAD---ISEC 
Figure 6: Road Object. 
It would be possible to introduce another relation LINK to 
separate objects and relations like shown in Figure 7 but in 
practice this is not necessary. 
ISEC---LINK---ROAD---LINK---ISEC 
Figure 7: Alternative construction of road objects. 
4.2 Relations 
Relations are connecting the objects of a given sketch or 
reference data set but are modelled in the same way as the 
latter. They are nodes of the description graph and define links 
to other nodes, representing objects or other relations. 
Some of the relations are connecting other nodes and provide a 
certain meaning to this connection but some are only linked 
with one node which has the meaning of adding information to 
the target node. 
The ISEC objects are the result of incident road segments at an 
intersection. But after introduction of an ISEC instance the 
information about the cardinality information is discarded. The 
cardinality information can be reintroduced by using the classes 
C1, C2, C3, C4, C5, ..., CN where CN means there are exactly 
n or more than n road segments (Figure 8). 
   
   
  
  
  
  
   
  
    
   
  
   
   
  
  
   
  
   
  
  
  
   
   
  
  
   
   
  
    
  
  
  
  
   
   
   
   
   
  
   
   
   
    
   
    
   
   
    
   
   
   
  
   
  
  
    
   
    
	        
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