parameters of the panoramas (X,Y,Z,) differ significantly 
from the approximate values. Standard bundle adjustment 
would often fail for such configurations. Since tie points can be 
distributed all over the horizon of a panorama, the here 
presented approach is reliable and robust. Up to now there is no 
experimental set-up where the process failed. A remarkable 
advantage of this approach is the limited number of required tie 
points. Recent investigations have shown that a total of 5 to 7 
points is sufficient for a complete room. 
4.3 Achieved accuracies 
The achieved accuracies asre mainly based on the following 
criteria: 
= quality of camera calibration 
= quality of tie point measurement for panorama generation 
= quality of tie point measurement for panorama orientation 
= distribution of panoramas inside the room 
In order to assess the first three topics theodolite measurements 
of control points (better than 1mm) have been carried out. 
Subsequently the whole process has been tested based on 
ellipse-operator measurements of circular targets on one hand, 
and manual cursor measurements of natural points on the other 
hand. The observed object space has dimensions of 14m x 12m 
x 2.5m. Tab. 1 summarizes the deviations of adjusted object 
coordinates with respect to the theodolite results. 
  
circular targets natural points 
  
mean deviation 21/25/03 10,1/98/2,53 
  
max. positive deviation 31/68/19 16,5 / 16,7 / 4,2 
  
  
  
  
max. negative deviation -7,3/-7,4/-1,6 | -15,3 / -9,6 / -2.0 
  
  
  
Tab. 1: Deviations of adjusted coordinates compared to 
theodolite measurements (X/Y/Z, in mm) 
Compared to signalised targets the use of natural tie points 
leads to worse results, mainly due to the limited detectability of 
those image points. However, for applications with less 
accuracy specifications even natural tie points may yield 
sufficient results. Since no targeting is used the effort for object 
preparation and in-house measurements is drastically reduced. 
Besides image acquisition only a few (minimum 1) object 
distances have to be measured on-site. 
5. 3-D OBJECT RECONSTRUCTION 
After orientation object points can be measured by spatial 
intersection. Usually edge and corner points of object features 
are used as object points. Since there is no fully-integrated 
program environment available, measured object points are 
transfered into a 3-D CAD system such as MicroStation where 
the final modeling is performed. Fig. 15 shows an example of a 
3-D room model with interior furniture. 
6. SUMMARY AND OUTLOOK 
The presented approach for generation and use of panoramas is 
an efficient and cost-effective method for the reconstruction of 
3-D object information with photogrammetric precision. While, 
for interior room surveying, the standard multi-image approach 
of close-range photogrammetry leads to a relative high number 
of images with rather weak configuration, only 3 or 4 
panoramas are required. If only room inspection is desired, only 
one panorama would be sufficient. A small number of tie points 
has to measured, usually only 5 to 7 points. 
Future works will concentrate on the implementation of 
automatic matching algorithms for the stitching process of 
adjacent images. This step should increase accuracy by using a 
higher number of tie points whereby manual interaction are 
reduced. 
In addition, the mathematical orientation model will be refined 
in order to provide higher accuracies for object reconstruction. 
An integrated program environment is currently under 
development. 
  
  
  
  
  
  
  
  
  
  
Fig. 15: Example 3-D model made by panorama object 
reconstruction; left: measured object information; right: 
rendered 3-D view 
7. REFERENCES 
Düppe, R.-D. (1998) Beispiele zur Umbildung von 
Weitwinkel-,  Panorama- und  Fisheyeaufnahmen im 
Nahbereich. Allgemeine Vermessungsnachrichten, Karlsruhe. 
Hóhle, J. (1998): On the production of photorealistic and 
dynamic 3D-models of building structures by means of digital 
photogrammetry, Proceedings Visual Reality, pp. 141-150. 
Hóhle, J. & Pomaska, G. (1999): Zur Visualisierung von 
Gebàudemodellen und deren dynamische Repräsentation im 
Internet, http:/www.imagefact.de/sokrates/d/jhgp.html 
Lisowski, W. & Wiedemann, A. (1999): Auswertung von 
Bilddaten eines Rotationszeilen-scanners. Publikationen der 
DGPF, Band 7, pp. 183-189. 
Pomaska, G. (1998): Automated processing of digital image 
datat in architectural surveying. IAPRS, Commission V, 
Hakodate, Japan or http:/www.imagefact.com 
Scheele, M, Borner, A., Reulke, R., Scheibe, K. (2001): 
Geometrische Korrekturen: Vom Flugzeugscanner zur 
Nahbereichskamera. Photogrammetrie-Fernerkundung-Geoin- 
ormation, Heft 1, 2001, pp. 13-22. 
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