sensor in several test flights [Ackermann, Lindenberger & 
Schade 1992],[Ackermann, Englich & Kilian 1994]. 
Mirror 
  
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Figure 1: Principle of a laser line-scanner 
The technical development in the last years made a new 
generation of laser sensors available. Those laser scanners 
permit an area covering measurement of topographical ter- 
rain surface with a high point density. To allow an area 
covering data capture with a laser sensor the laser beam 
has to be deflected periodically. Within the system used 
to provide our test data sets, the deflection is performed 
by a nutating mirror, which sends the deflected laser beam 
through a linear fiber-optic array. The fiber-optic array 
consists of different single optic channels with different 
viewing directions. Therefore the laser scanner virtually 
defines a push-broom-system, which -in combination with 
the movement of the system in flight direction- results in 
a strip-wise data acquisition. Figure 1 shows a schematic 
picture of a laser line scanner. Table 1 summarizes the 
main parameters of a laser scanner of this type [Lohr & 
Eibert 1995]. The main advantage of the additional use of 
a fiber optics, is the stability of the direction of the laser 
beam in a highly kinematic environment like an aircraft. 
The mechanical swinging mirror might be deflected addi- 
tionally and uncontrolled by accelerations of the aircraft 
during the flight. This results in a distorted direction of 
the laser beam, which is corrected by the fiber optics. 
  
sensor type 
pulse modulated Laser Radar 
  
scanning principle 
fiber optic line scanner 
  
range 
< 1000 m 
  
measurement principle | run-time measurement 
  
scan frequency 300 Hz (adjustable) 
  
  
  
  
field of view +7 
pixels per scan 127 
swath width 250 m 
at 1000m flight height 
accuracy of a single < 03m 
distance measurement 
  
  
  
laser classification class 1 by EN 60825 (eye-safe) 
  
  
Table 1: Performance parameters of the used laser scanner 
The laser rangefinder, used in an airborne laser sensor sys- 
tem has to meet a few physical characteristics to be suitable 
as sensor for the measurement of the topographical terrain 
surface. One important aspect is the wavelength of the 
laser rangefinder. To measure points on the earth surface, 
the laser beam should not penetrate into the ground. This 
can avoided by using a wavelength in the near infrared. 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996 
Another important requirement is the use of a pulsed laser 
rangefinder, which is able to registrate the last reflected 
parts of the emitted pulse. Even though some pulses are 
completely reflected by leaves or branches of the veget- 
ation, in many cases the reflected pulse will refer to the 
terrain and can therefore be used to determine the terrain 
surface. 
2.2 DETERMINATION OF THE ABSO- 
LUTE ORIENTATION 
In order to perform the evaluation process the laser scanner 
data has previously to be georeferenced. In this process the 
exterior orientation of the laser sensor at the time of meas- 
urement is determined. The determination of the absolute 
orientation (position and attitude) of the laser sensor at 
the time of measurement is necessary to derive the ground 
coordinates of the laser points. 
Different sensors can be used to measure directly the ab- 
solute orientation of the laser sensor at the time of meas- 
urement. Using either inertial navigation systems (INS) or 
a multi-antenna GPS receiver or a setup of several GPS 
receivers, the exterior orientation of the sensor can be ob- 
tained directly. 
Either the INS or the GPS can be used as a single sensor 
to perform the positioning and the attitude determination 
of the laser sensor. But due to the error characteristics of 
both sensors, GPS is used to provide the positioning and 
an INS is used for the attitude determination. 
The positions, measured with GPS, and the attitudes, 
measured with the INS, have to be interpolated to provide 
a position and attitude for each laser measurement. The 
GPS data are of a relatively low data rate (up to 10 Hz), 
in comparison to the data rate of laser scanner (1000 Hz 
and more). Therefore a model of the flight path of the air- 
craft and an interpolation of the positioning parameters is 
necessary. Another possibility to condense the positioning 
information provided by GPS, is to use additionally rel- 
ative positions from the INS, which are measured with a 
higher data rate (e.g. 100 Hz or more). 
3 EVALUATION OF LASER 
SCANNER DATA 
Combining the GPS/INS system for the determination of 
the exterior orientation with an laser sensor for distance 
measurement, a powerful system for the direct 3D meas- 
urement of the topographical terrain surface is available. 
To derive a Digital Terrain Model from the measured data 
a lot of single evaluation steps are necessary. Roughly 
spoken, four main evaluation steps can be distinguished 
during the processing. 
3.1 Preprocessing 
During the preprocessing task, the ground coordinates of 
the laser points are derived from the raw data provided by 
the laser scanner and the orientation sensors. Therefore the 
measurements of the different sensors (GPS, INS and laser 
scanner) have to be synchronized, the positions and atti- 
tudes have to be determined for each single laser measure- 
ment. Then the synchronized measurements can be trans- 
   
  
   
    
  
  
    
      
    
    
     
   
    
    
    
  
   
     
     
  
    
    
    
     
   
   
   
   
   
   
    
   
   
    
   
   
   
    
   
   
   
     
  
   
   
    
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