International Archives of the Photo 
grammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
  
Figure 2: (a) left-search surface, (b) centre-template surface, (c) 
right-search surface, (d) obtained 3D point cloud after LS3D 
surface matching, (e) shaded view of the final. composite 
surface. 
The second experiment refers to the matching of two 
overlapping 3D point clouds (Figure 3), which are a part of a 
chapel in Wangen, Germany, and were scanned using IMAGER 
5003 terrestrial laser scanner (Zoller+Frôhlich). Initial 
approximations of the unknowns were provided by interactively 
selecting 3 common points on the both surfaces before the 
matching. Obtained results are given at part II of Table I. The 
estimated oy gives valuable information about the sensor noise 
level and the accuracy limit of the scanner as 71 7 mm. 
Table 1: Experimental results 
5 n i t d 50 Oi /Oy 167 O6, / Gy / Oy 
  
  
  
  
sec mm mm mm e 
LL. P 2497.7 06 15 0.9 0.15/0.07/0.05  0.96/2.44/1.90 
B 9. da 0.19 0.15/0.07/0.05 0.96/2.42/1.91 
IR P 32856 0:5, 1.5: 021 0.13/0.03/0.05 0.68/2.25/1.73 
B 6 1.4 0.21 0.13/0.03/0.05 0.69/2.26/1.75 
Il P-13461 5o 380-0 1.74 0.23/0.62/0.01 0.69/0.17/0.46 
B 4:56 1.72 0.22/0.61/0.01 0.69/0.17/0.46 
  
  
  
  
-R: right face surface, II: laser scanner data 
I-L: left face surface , 
Jlane, B: bi-linear surface, n: number of 
s: surface representation, P: | 
employed points, i: iterations, t: process time, d: point spacing 
arametric bi-linear surface representation gives a slightly 
The p 
a better a posteriori sigma value 
better convergence rate and 
than the triangle plane representation, while increasing the 
The standard deviation of the z- 
computational expenses. 
ion vector shows the excellent data 
component of the translati 
content in the depth direction, but the relative precision is 
highly optimistic, which is ~1/1000 of the point spacing. 
Since LS3D reveals the sensor noise level and accuracy 
potential of any kind of surface measurement method or device, 
it should be used for comparison and validation studies. 
Ee 
ON 
: a 
nm cmm 
HET OI RHET 
M réal 
ii ghia 
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(a) (b) 
Figure 3: (a) top - template surface patch, (a) bottom - search 
surface patch, (b) overlay of the shaded surfaces. 
4. CONCLUSIONS 
LSM is a fundamental measurement algorithm, and has been 
applied to a great variety of data matching problems due to its 
strong mathematical model. Two well-known ones are LS image 
matching in 2D pixel space, and LS multiple cuboid matching 
in 3D voxel space. The LS3D is bridging the conceptual gap 
between the LS image matching and the LS cuboid matching. 
This new 3D surface matching technique is a generalization of 
the least squares 2D image matching concept and offers high 
flexibility for any kind of 3D surface correspondence problem, 
as well as monitoring capabilities for the analysis of the quality 
of the final results by means of precision and reliability 
criterions. Another powerful aspect of this proposed method is 
its ability to handle multi-resolution, multi-temporal, multi- 
scale, and multi-sensor data sets. The technique can be applied 
to a great variety of data co-registration problems. In addition 
time dependent (temporal) variations of the object surface can 
be inspected, tracked, and localized using the statistical analysis 
tools of the method. 
ACKNOWLEDGEMENT 
The author would like to thank Dr. Nicola D'Apuzzo for 
providing the face surface data sets, which were measured by 
use of his own software Viewrriplet GTK v0.9€. The laser 
scanner data set is courtesy of Zoller+Frôhlich GmbH 
Elektrotechnik (Wangen, Germany). 
REFERENCES 
Bergevin, R., Soucy, M., Gagnon, H.. Laurendeau, D., 1996. 
Towards a general multi-view registration technique. [EEE 
c 
Pattern Analysis and Machine Intelligence, 18(5), pp. 540-547. 
, 
Besl, P.J., and McKay, N.D., 1992. A method for registration of 
3D shapes. /EEE Pattern Analysis and Machine Intelligence, 
14(2), pp. 239-256. 
Campbell, R.J., and Flynn, P.J., 2001. A survey of free form 
object representation and recognition techniques. Computer 
Vision and Image Understanding, 81(2), pp. 166-210. 
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