anning 
search 
ular in 
felling. 
. block 
gations 
; under 
len 3D 
beider 
en aus 
rischen 
n einen 
it nach 
je erste 
suchten 
relative 
wanteed 
vidually 
]ynamic 
bination 
t and à 
tcoming 
| over 4 
degrees 
field of 
ioned in 
he laser. 
nages of 
; usually 
also the 
fficiency 
ments is 
lures are 
urements 
by laser 
pport the 
low the 
re which. 
Jence, by 
jable and 
| this sort 
Vision”. 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
Table | shows a comparison of several sensor characteristics. It 
clearly demonstrates the partly low correlation between both 
instrument properties what leads to the conclusion that both 
echniques may complement each other in an ideal way. 
  
  
  
  
  
  
  
  
  
  
  
  
  
Laser Scanner Photo Cameras 
| Spatial Resolution High Very High 
| Spatial Coverage Very Good Good 
! Intensity/Colour Limited Very Good 
Illumination Active Passive (& Active) 
3D Pt Density High Depend. on Texture 
| Depth Accuracy High High 
Acq. Procedure Dynamical Moment Shot 
( 3D Reconstr. Effort Medium High 
Texture Reconstr. | No or Very Limited Very Good 
Instrument Costs High Low 
  
  
Table 1: Comparison of Sensors 
While accurate and efficient photogrammetric reconstruction 
procedures are state-of-the-art (many commercially available 
software packages exist) and may be automated to a high extent, 
processing and compilation of laser scans still need further 
development. The hardware is still under development too and 
significant improvements may be expected for the future, 
although a high degree of precision, reliability, and practi- 
cability has been reached. A wide range of laser scanner models 
are available and several companies turned out to have gained a 
significant position on the world market. One of those 
companies is Riegl Laser Measurment Systems GmbH, Austria 
(see ww w.riegl.com). Close co-operation exists with LP.F. and 
in near future also with the Christian Doppler Research 
Laboratory for "Spatial Data from Laser Scanning and Remote 
Sensing" (LS&RS) which was founded in 2003 and is integ- 
rated in LP.F.'s activities. The Austrian company No Limits IT 
GmbH, a subsidiary company of Geodata Austria, (see 
www.citygrid.at) is also partner of the LS&RS. This company 
has developed a “CityGRID Scanner” (Forkert, 2004) 
consisting of a Riegl Laser Scanner and a digital camera. The 
device is mounted on a motorised vehicle which moves through 
the road of a city and acquires building facades in three 
dimensions together with the building texture. A highly auto- 
mated reconstruction procedure for efficient scanning is 
currently under development which should allow the generation 
of a detailed virtual urban environment in a fast and affordable 
way. 
2. ORIENTATION AND RECONSTRUCTION 
In order to achieve the optimum results in terrestrial laser 
scanning, the utilisation of both range imaging and photo- 
grammetric imaging is the preferred approach. Consequently, 
also the reconstruction process has to concentrate on the 
concurrent usage of both imaging products, by fusing the data. 
The fusion can be applied during two fields of compilation: 
*Orientation of sensors 
* Object reconstruction 
The first work is responsible for establishing a uniform and 
geometrically consistent block of measurements from both laser 
Scanner and the photographic images. Basically two set-ups are 
possible. One set-up uses totally independent positioning of the 
laser scanning device and the photogrammetric camera, the 
other uses a combined, stable and calibrated arrangement of 
laser scanner and camera. The geometric relation between 
949 
camera and laser scanning device is given by the so-called 
mounting calibration, which has optimally to be determined in 
advance and serves as a sort of interior orientation of the 
acquisition system. 
While the combination of both acquisition techniques offers a 
series of advantages for the orientation of the sensing system, as 
we shall see later, data fusion may also be used for the object 
reconstruction procedure where range and intensity data 
complement each other. Matching of individual scans and/or of 
individual photographic images can be supported by 3D object 
data as well as by 2D radiometric data. Thus, the geometric 
accuracy, the reliability and the completeness of the recon- 
structed object can be improved. In particular objects with 
complex shape and/or texture benefit from the combination of 
both acquisition techniques. 
2.1 Orientation of the sensor set-up 
2.1.1 General Remarks 
In order to describe the geometric properties of the sensors and 
in order to define a homogeneous coordinate system for the 
object reconstruction, the different sensor observations must be 
transformed into one global object co-ordinate system. À hybrid 
adjustment approach provides the ideal means for determining 
both the internal and the external sensor geometry. The Institute 
of Photogrammetry and Remote Sensing of the Vienna 
University of Technology has been working on problems of 
bundle block adjustment techniques for years. The software 
packages ORIENT and ORPHEUS are the result of this 
research activities (Orpheus/Orient, 2004). This universal 
approach realized in ORIENT can easily be adapted to various 
acquisition techniques, even to the simultaneous orientation of 
different techniques as in the case of laser scanning and 
photographic imaging (Ullrich, et al., 2003). 
For block adjustment tie points have to be measured which not 
only tie the individual images and laser scans to each other but 
also link the range measurements to the photographs. Control 
points or control information, i.e. points with known position or 
other known geometric properties with respect to a higher level 
co-ordinate reference system, are necessary only to define the 
orientation of the reference system. The scale can exactly be 
determined by the range measurements. The translation. and 
rotation parameters may, for example, be defined by one control 
point and additional so-called fictitious observations, such as 
horizontal plane, vertical plane, lines with known spatial 
orientation, etc. 
2.1.2 Solution in Riegl Systems 
Riegl Laser Measurement Systems GmbH has recently started 
to offer, as an option, their 3D laser sensors together with a 
firmly mounted high-resolution digital camera. Due to the well- 
known camera calibration and camera orientation with respect 
to the scanning device the entire equipment can be treated as a 
single hybrid acquisition system. The measurements are stored 
on-line on a mobile computer (connected to the scanner through 
a high speed data link) in an indigenous structured format 
which contains all relevant exterior and interior sensor 
parameters thus making separate alignment procedure 
unnecessary. The data format is defined in XML and is open to 
everyone thus enabling data export and import between various 
utilities and any-post-processing software. 
The software package RiScan Pro organises data acquisition, 
calibration, visualisation and archiving, and prepares data for