International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part Bl. Istanbul 2004 
  
the Rollei db23 camera enables photogrammetric aerial surveys 
(60% end lap) with a ground resolution of > 12 cm. The digital 
back works together with a Rolleiflex 6008 Integral camera 
body and a Zeiss distagon 4/50-lens with a min exposure time 
of 1/500 s. The digital camera is controlled by a laptop, which 
also stores all the image data via a firewire connection. 
Table 1: Technical parameters of the digital Rollei db23 camera 
  
  
  
    
Rollei db23 
  
  
  
    
    
     
  
  
  
  
   
     
    
  
Camera type Rolleiflex 6008 with fixed digital 
back 
Resolution 3.036 * 2.032 
Pixel size 12 um * 12 um 
36.67 * 24.38 
Colour depth per channel 12 Bit 
Sensor size [mm] 
€ 
min. exposure interval ca. 1.8' se 
Weight (incl. camera) ca. 1,500 g 
Connection to computer — Firewire, MS-Windows notebook 
Software Phase One 2.7 
  
    
     
     
   
  
  
      
  
  
  
    
   
   
  
   
   
    
   
   
   
  
    
    
  
   
   
   
   
   
   
   
     
    
    
i 7 5 = i 
value for two consecutive images, for secure image recording 
of a strip add 50%. 
Other important components of PFIFF are the GPS-based flight 
management system and a navigation unit that automatically 
triggers the images during a flight strip according to the pre 
defined end lap. The navigation unit records the exposure delay 
of the camera as well as the approximate parameters of the 
exterior orientation with an attitude heading reference system 
(AHRF). The AHRS consists of a digital compass and a two 
axis inclinometer. The exposure control is coupled with the 
PPS-signal of the GPS-clock to ensure a perfect synchronisation 
with the external high accuracy L1/L2-GPS receiver. 
For a photo flight the system is temporarily installed in a Cessna 
172 with a small ground hole of ca. 12 cm in diameter. See 
Figure 1 for the system design. 
Navigation Digital Image Acquisition System 
Position (X, Y,Z) AHRF (0.9.x) 
passes L1/L2-GPS GPS 2 axe inclination- 
GPS i : 
(Garmin II Plus) (Leica SR 399) — (Garmin 25) sensor (ap)  Compass(x) 
| 
| 
Survey / Navigation ees ,. Li 
>» 
  
(Laptop with Cartalinx) Nav. PC A/D 
ss m = (Pent. 90) 
- 
D 
o 
“osindwi 196611 — 
esinduij use|4 
Digital Camera 
  
— 
(Rollei db23) Firewire | 
Passive stabilisized Laptop 
camera platform (24 GB hard disc) 
Figure 1: Low-cost remote sensing system PFIFF 
For the use of a digital camera in aerial surveys not only the size 
of the CCD-sensor is of importance, but also many other criteria 
of the digital camera such as the minimum exposure interval, 
the external storage capacity, a continuous power source, 
preview options, the mechanical stability of the sensor (interior 
orientation), the temporal eccentricity (exposure delay), the 
reliability and also the radiometric properties have to be 
considered and determined. Therefore the system has undergone 
thorough geometric and radiometric calibration procedures. For 
photogrammetric work the interior orientation of the camera 
was determined. With the fixed digital back of the db23 an on- 
flight calibration is not necessary. The examination of the 
linearity, the spectral characteristics of the RGB band filters and 
the high signal to noise ratio revealed that the radiometric 
properties of the digital camera are superior to an equivalent 
photographic system. 
2.2 Practical experiences with PFIFF 
Between 1999 and 2004 single components and PFIFF as a 
whole was well tested in over 70 aerial surveys with more than 
8.000 images recorded. The sensor system was tested in the lab 
as well as under airborne conditions with an additional geodetic 
GPS receiver and a multi antenna GPS on board of the 
aeroplane to explore the accuracy potential for direct 
georeferencing of the system. 
The first photogrammetric test-flight in Nov. 2000 revealed the 
full geometric potential of the system, allowing sub pixel 
accuracy without ground control points through aerotriangu- 
lation and high accuracy GPS-receivers. Through the 
comparison of the exterior orientation parameters of both 
systems the absolute positional and angular accuracy of the 
GPS/AHRS-system could be determined. The accuracy 
assessment is complete because the residuals of the orientation 
parameters as well as the calibration errors of the optical system 
and errors of the sensor orientation are incorporated in the 
difference vectors to the well known ground control point co- 
ordinates. 
Due to large number of images (^ 2.000 per vear) the 
management and archival of the image data and the meta data is 
quite a challenge. The meta data collection has been automated 
with several routines and special avenue scripts. For a 
convenient search and ordering of data via internet a JAVA 
based inquiry tool was developed. 
2.3 Flight planning for high ground resolution aerial 
surveys 
In the flight planning for urban surveys several special issues 
have to be considered. The surveys are generally done at low 
altitudes and thereby take place in a turbulent flight zone, 
especially during the summer when the urban heat dome 
introduces additional thermal turbulences. For surveys with a 
high ground resolution (12 — 15 cm) the minimum exposure 
interval at normal ground speed of the aircraft (40 — 55 m/s) 
becomes critical. A flight with reduced speed (30 — 40 m/s) 
however decreases the stability of the airplane furthermore. This 
causes higher deviations in the roll, pitch and heading angle. 
Due to the lack of an active stabilized mount a high side lap of 
more than 30% has to be considered in the flight planning. 
A further source of inaccuracies may be caused be image 
motion due to the ground speed of the aircraft. Additionally 
image motions due to rotations and vibrations of the aircraft 
during image acquisition also occur. For digital images the 
resolving power of the lenses is generally better than the pixel 
resolution and therefore the image movement shall be no larger 
than one pixel to maintain a sharp image. The image motion 
may become a limiting factor for PFIFF at high ground 
resolutions, because the minimum exposure time of the lens is 
1/500 s. 
3. EXAMPLES 
To demonstrate the potential for urban and agricultural 
applications of PFIFF two recent projects will be described in 
   
Inter! 
— 
more 
grour 
3.1 
The 
consi 
appre 
" 
cm/p 
see fi 
The 
give 
statu: 
decis 
betw 
inter] 
withi 
aerot 
GPS- 
post 
persp 
preci 
the : 
headi 
foun 
Figu 
pers; 
For 
grou 
intro 
GCE 
natu 
pres 
enhe