value to know whether it would be vegetation. The red to 
orange areas, which lack of blue homogeneity and green 
vegetation, is more likely the concrete covered areas and 
damage areas, if working on a post-disaster image. This is 
particularly true for the area at the top-left of our study area. In 
the case that a pre-event image was available, it would be able 
to detect the wash-away areas and possibly wet areas due to 
tsunami attack via change detection. 
Figures 5 and 6 present the results of fine level processing of 
two selected areas, in which the extracted features presented in 
their identification numbers (ID) and their ‘class’; the ‘class’ 
here is the combined results from pixel-based spectral, 
morphological, shape indices as a result of multi-criteria 
evaluation. The colour code for ID is just to discriminate the 
adjacent ones. Two clusters with the same colour but not next 
together do not have the same ID number. Figure 5 explores 
further the details of a damage area whereas Figure 6 presents 
the result from the non-damage area full of old rooftops. 
  
Figure 6. Fine level processing results of a non-damage area 
Combining the evidences from both coarse and fine levels, a 
disaster-induced damage area can be confirmed. Current 
satellite spatial resolutions are unable to report detailed damage 
information at building level but only can delineate the non- 
collapse buildings and debris areas. The damage ratio is then 
computed approximately. Existing method prefers the pixel- 
based computation on a grid-based form, i.e. the ratio of number 
of collapsed pixels to total number of pixels in a cell. With the 
coarse level clusters by the developed solutions, the 
approximate damage ratio would be better and probably more 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
easy to use in practice. One of the main reasons is that the street 
network is usually the boundary of administrative units and also 
clearly presented in satellite images, which lead the merging to 
follow. 
Accuracy assessment of detected information from satellite 
image remains a big challenge though remote sensing images 
have been employed in disaster management for decades. It is 
mainly due to the gap between what remote sensing can produce 
and what the disaster management practitioners demands and 
get used to. There has been also a discussion on how damage 
information should be presented. Consequently, previous 
research (Gusella et al. 2005, Stramondo et al. 2006, Vu and 
Ban 2010) faced the difficulty in comparison with the ‘ground 
truth" information. 
In this paper, the detected buildings are simply crosschecked 
with the visually detected ones. It showed that as Figures 4, 5 
and 6, the extracted results were reasonably matched with the 
reference ones. Most compact objects, more likely to be 
building rooftop, were well detected. Visually, the old house 
rooftops in the study area are not distinguishable from the 
surrounding implying that it would be tough for an automated 
processing as illustrated in Figure 7. The occlusion by the trees 
nearby also cleared a possible separation line between 2 objects 
introducing omission errors. More quantitative assessment will 
be reported in a mutual acceptable form with disaster 
management practitioners. 
  
True Colour Composite False Colour Composite iD 
Figure 7. Difficult situation for automated recognition 
4. CONCLUSION 
Dual-scale processing framework has been introduced to 
support the rapid damage estimation at the early stage after a 
disaster. The initial development is to serve as part of a system 
for tsunami disaster damage estimation while its ultimate goal is 
to serve as early damage estimation solution for multi-type 
disaster in support of emergency responses and to distribute for 
detailed damage assessment. The test with QuickBird image of 
Ban Nam Ken, Phanga, Thailand produced a reasonably good 
result. 
The result from coarse level delineated the highly suspected 
damage areas and produced the focused boundaries for fine 
level processing. The fine level processing designed as a semi- 
automatic approach then helps to explore the damage areas in 
further details and detect the non-collapsed buildings. The 
combination outcomes from both levels would enable the 
derivation of better damage ratio index. The solution was 
designed aiming at a parallel implementation, and detailed 
report of the computation time will be reported in next 
publication. However, to suit the available platform of various 
users, different way of implementation will be considered 
including multi-core CPU, GPU and grid platform. It is 
recommended to develop a suitable method for accuracy 
     
    
     
    
    
   
    
    
    
   
    
    
  
   
   
    
  
  
  
  
  
   
    
  
  
   
   
   
      
   
  
  
  
  
  
    
  
  
   
   
      
     
     
     
      
       
Interr 
assessmen 
mapping. 
This stud 
project su 
Program 
Industrial 
Japan. Th 
Faculty of 
Malaysia 
Adams, I 
Shinozuk 
Satellite 1 
2003 Bo 
Multidisc 
Progress 
Buffalo. 
SP01/12. 
Balz, T. : 
post-seisi 
Journal c 
Bogaert, 
Alternati 
compacti 
Computc 
Bevingtc 
Debuts 
http://ww 
Blaschk: 
sensing. 
Sensing, 
Chesnel 
Assessir 
High R 
Sensing 
Ehrlich, 
2009. ] 
earthqu: 
Journal 
Goodch 
geograr 
frontier 
Gusella 
A, 20 
earthqu 
earthqu 
Kerle, 
2006 I 
Journa 
pp. 46€