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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
Data processing stage has followed data acquisition to provide a 
cartographic representation of collected data, to support quarry 
management and to allow geological analysis. 
Laser data and digital image have been processed using the 
Reconstructor software developed by the Joint European 
Commission Centre (Sequeira V. et al.,1999) according to the 
following steps: 
l. range scans pre-processing, editing, geo-reference, 
meshing and texturing; 
2. geometrical information extraction (cross-sections, 
surface measures, iso-lines) and DSM generation; 
3. geological analyses. 
Pre-processing is performed immediately after data capture and 
includes /ocal surface normal computation. This information is 
a very valuable support for next geological analyses. 
A fully GCP-based registration method has been adopted. The 
software allows also a feature-based registration (ICP method) 
which could be useful for comparison with future acquisitions. 
Starting from the actual survey which can be chosen as 
reference and registering to it all the other range scans, it will 
be possible to verify quarry temporal changes. Reconstructor 
provides tools to build 3-D models and perform automatic 
comparison between models built at different time of the quarry 
life. 
An intelligent data reduction is provided through a multi- 
resolution meshing process which converts the set of the raw 
3D points into a continuous surface. The Reconstructor 
software allows mapping external 2D images on the 3D mesh; 
color information enriches geometrical information helping the 
geological data interpretation. 
The data processing creates a texture-mapped 3D model of 
quarry containing the complete geometric 3D and 2D 
information. The software becomes a virtual surveying tool, 
which extracts the information from 3D and 2D surveyed data 
and hands it over to standard software for cartographic 
representation and DEM generation. 
Major results of the marbel quarry laser survey campaign have 
been: point and distance measurements, area and volume 
measurements, interactive and automatic fitting of planes, 
creation of cross-sections, DEM generation,  iso-lines 
cartographic representation (see Figure 5). 
This dataset of results and products constitutes a valid support 
for geological and geo-mechanical analyses of the excavation 
area, requiring both geometric and colorimetric data. 
  
Figure 5: Processed range scans used for geological analysis: 
different colors correspond to different quarry slopes 
713 
4. FINAL DISCUSSION 
In the paper some technical aspects of the application. of 
terrestrial laser scanning to survey site of interest by geological 
purpose have been presented. The current availability of long 
range TLS becomes possible the operational use of this survey 
tool, which may provide products that cannot be obtained by 
other topographic and photogrammetrye methods, or can be 
obtained with a largely minor effort and consumed time. 
Two tests leaded by the research groups of the authors have 
permitted to have a look on practical methods, solutions and 
problems as well. Within the main advantages of laser survey 
applied to geology, the following can be listed: fast data 
acquisition due to remote data collection (direct survey of 100 
m? surface can require around 2 hours to an expert operator); 
completeness with respect to traditional survey using "spot" 
data acquisitions (1 local spot survey every | kn; increased 
measurement accuracy (e.g. in traditional geological survey, 
local compass measurements are still collected to establish 
attitude of discontinuities). 
Further developments either in algorithms and procedure for 
registration, and in application and operational aspects have to 
be carried out in the near future. A laser scanning survey results 
in several hundreds of Mb data, which are still difficult to be 
managed by commercial softwares and common PC. 
Optimization of processing and visualization tools is needed, 
while techniques to optimize the survey planning in order to 
reduce the size of point-clouds from the acquisition stage are 
expected. 
ACNOWLEDGEMENTS 
We would like to thank Simone Orlandini (MicroGeo, Firenze, 
Italy) and Riegl company (Horn, Austria) for having provided 
TLS instruments used in both experimental tests. 
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