108 
Mus 
i. 
LE 
108 b t 
107 4 
d 
ios r1 
s 
105 = 
8 
a3 
108 2 
x 
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103 si 
3 
  
  
    
Yi / 
Figure 12. Graphic representation of the comparison, carried 
out with the above mentioned program, between the 
photogrammetric sections and the corrisponding sections on the 
registered cloud of points 
We have chosen to use the array of sections, obtained by photo- 
grammetric models, as a reference for testing laser data. 
In fact, they correspond to the following requirements: they are 
representative in a homogeneous way of a tested area, the accu- 
racy is known and they are indicative of the shape of the object 
with a sufficient density, able to be compared with laser scanning 
data. On the other hand, the measurments taken with topographic 
and photogrammetric techniques are normally referred exactly to 
those elements (edges, cornices, ...) not well-defined with laser 
scanning. Therefore, these deviations are not related to the nodes 
of the photogrammetric plot, but to those points which are able to 
LtegaíTileFot() íegatifiletssii 
Photogrammelric plotting Laser scanning acquisition data 
acquisition data (section) (strips of points) 
OráinaFunttlase:sl 
Ordering laser scanning deta by 2 
decreasing 
Interpularet{} 
Medium point definition for each 
plotted segment (calcule z valo for 
following comparison) 
  
5ráinabatiCoepistiil) 
Compilation of ordered st of all 
L—— points {photogramenetric and ker 
scanning data} 
input. ange width for searching 
laser scanner data ta be considered 
  
Calcoialinterpolartionilaserfesata(]| 
  
1 ch 4 Interpolation CalcolalnterpolarionilaserMirnguad(] 
Vyesaht decraising with square ^ 
distance from reference point ee Sarna dola wee Least square interpolation 
eriteria 
ViscsiitfrfsRiseltatif] 
  
  
Output result report 
Figure 13. Flow chart of the program aimed at the 
comparison between the sections 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004 
better describe the surface. The aforesaid points were chosen as 
medium points between two subsequent nodes of the plotted 
polylines. At the end, we evaluated the deviations between the 
photogrammetric sections and the corrisponding sections of the 
registered cloud obtained as described in the sequel. 
The residuals are < +1 cm. 
4.4.1 Laser scanning sections: To make a point by point 
comparison between the photogrammetric plots and the laser 
scanning, with an automatic procedure, a Visual Basic program 
was developed. The flowchart in figure 13 shows its working. 
1. To have an important sample of laser data, strips of points, 1.5 
- 2 cm wide, were cut out. The corresponding photogrammetric 
section was plotted at x value equal to the center of the strip. 
2. After having verified that there are not considerable variations 
in x direction, in the examined thickness of the strip, x value has 
been ignored: this is like projecting the points of every strip on zy 
planes. 
3. Photogrammetric data are ordered according to the sequence of 
the plotted polyline vertices. For each segment a medium point is 
calculated and its z value is stored for consequent comparisons. 
4. A subroutine orders laser scanning data by decreasing z. This 
criterion is true in the portions with a vertical tendency but it is 
not appropriate in the horizontal one, where z value does not 
indicate the correct subsequence of the laser data. In our case, the 
sections describe prevalently vertical surfaces; other criteria should 
be defined to generalize the approach. 
5. Different search ranges can be defined around the previously 
calculated medium point (step 3); in order to better define it, both 
the quantity of plotted points and the object shape have to be 
considered. 
6. A laser data interpolation is made with the purpose of defining 
those points with an y value corresponding to the previous stored 
z value. Interpolation can be performed according to two different 
criteria: 
a - the points included in the search ranges are weighted with 
inverse square distance from the point used as reference; 
b - a linear regression based on least-squares method is applied. 
7. At the end, for each calculated z value, both photogrammetric 
and laser scanning y value, are compared and visualized. 
5. CONCLUSION 
In this paper an accuracy evaluation of an architectonic 3d model 
by laser scanning has been carried out. The main phases of elabora- 
tion have been tested and a comparison with reported accuracy val- 
ues by the producer has been done. In general, we can say that the 
results are confirmed, also after registration, on the cloud of points 
but that the value proposed as *Modeled surface precision" (4 2 
mm)is valid only in case of simple surfaces (level surfaces, spheres...) 
while with complex surfaces (as the most common cases in the ar- 
chitectural survey) it is not quite favorable, even though it remains 
in the accuracy range required in the cultural heritage survey. 
ACKNOWLEDGMENTS 
The research has been financed by Italian Ministry of Education, 
University and Research (MIUR) project COFIN 2002 (Research 
Group Resp. Prof. Bruno Astori). The authors greatly thank: prof. 
Franco Algostino for his helpfullness in the data management 
ing. Marco Nardini (Leica) for laser scanner aivailability: arch. 
Luigi Venezia and arch. Andrea Violetti for their cooperation in 
the apse modeling. 
    
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
   
   
   
   
   
   
   
   
   
  
  
  
   
   
    
  
   
  
    
  
    
  
  
    
  
  
  
  
  
  
    
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