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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B3. Istanbul 2004 
disaster in local government. In this case, it is assumed that 
stereoscopic aerial photos and exterior orientation are available 
by GPS/IMU. Former digital terrain data such as DSM or 
digital maps is transformed based on exterior orientation 
parameters and 3D matching. Changed areas are detected as 
inconsistent texture or height anomaly. 
Evaluation tests were performed with actual aerial photos that 
were taken right after of the earthquake and several years later. 
2. CONCEPT AND STATISTICS 
This study is objected for timely observation of area damaged 
by earthquake, especially for buildings, by establishing 
automatic change detection system. Automatic change 
detection system is needed for a disaster area in its carly stage 
because such information is demanded for planning rescue 
mission or limiting the expansion of the damage. Fig.l shows 
the flow of urgent correspondence system for a huge earthquake 
occurrence, which is the target of this study. In this system, 
there are two typical cases of change detection approaches. The 
first one is a direct comparison method and the other one is an 
indirect comparison method respectively. : 
The assumptions for the two approaches are as follows. 
(1) For direct comparison method 
1) No orientation parameters for aerial photos before and after 
the earthquake are available except approximate geographic 
coordinate. 
(2) For indirect comparison method 
1) Stereo pairs of aerial imageries before and after the 
earthquake are available. 
2) Internal and external orientation parameters are known. 
3) 2D or 2.5D digital map data for buildings of target area are 
prepared in local government's spatiotemporal GIS 
(Geographic Information System) data server and are 
available for the change detection process. 
  
  
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Figure 1. Urgent correspondence system for a huge 
earthquake occurrence 
External orientation parameters are obtained by on flight 
analysis of GPS/IMU. 
In the first approach, we can use only single aerial imagery 
before and after the earthquake for the target area, which also 
means that no stereo pairs are available and 3D information is 
not acquired. In this case, change detection is executed by 2D 
comparison of images. We call this approach 2D image 
  
   
matching method and this process is realized with a unique 
registration method called adaptive nonlinear mapping in this 
study. 
On the other hand, indirect comparison method utilizes stereo 
pair imageries and orientation parameters in addition to digital 
map data. The changes of disaster area are detected as 3D shift. 
3. CHANGE DETECTION BY 2D IMAGE MATCHING 
METHOD 
3.1 Process Flow 
Fig.2 shows the process flow of 2D image matching method. In 
the first step, a pair of aerial imageries before and after the 
change is used to form an imaginary stereo model, which is 
objected for facilitating and stabilizing image matching process. 
In the next step, image matching is carried out. Geometrical 
registration processes such as affine transformation or Helmert's 
transformation are not applicable or sufficient for this process 
due to the influence of parallax. To solve this problem, 
adaptive nonlinear mapping method is applied in this study. In 
the last step, change area is detected as the inconsistent area of 
adaptive nonlinear mapping. The details of the processes are 
described in the following sections. 
  
Formation of imaginary 
stereo mode 
y 
Image matching by 
adaptive nonlinear mapping 
  
  
  
  
  
Detection of change area 
  
  
Figure 2. Process flow of 2D image matching method 
3.2 Formation of Imaginary Stereo Model 
Formation of imaginary stereo model is for reducing calculation 
time and increasing the stability of adaptive nonlinear mapping 
process. Fig.3 shows the processing flow for formation of 
imaginary stereo model. In the first step, pre-processing is 
conducted such as contrast adjustment by automatic process or 
adjustment of image resolution by manual process and so on. 
The next step detects matching points in a pair of images taken 
at different time. Either automatic or manual process is 
performed by the judgement of operator. The automatic 
detection realizes automatic detection of pass points with high 
accuracy from stereo model (Sakamoto et al., 1998). The 
principle is based on point matching with improved relaxation 
method and a mathematical model. If the automatic process 
fails to detect matching points, manual detection by operator is 
performed. 
In the next step, relative orientation parameters are calculated 
with matching points detected above. If the calculation is 
successful, formation of stereo model by image rectification is 
followed. Different from normal stereo model of aerial images, 
some case has been confirmed that the adequate stereo model 
cannot be generated since the difference of the altitude of 
photographing sites in two images. In this case formation of 
stereo model by perspective projection is applied instead of 
image rectification. 
Image rectification is based on epipolar geometry, which 
reduces the direction of mapping (matching) to x-direction only.