International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part BI. Istanbul 2004 
  
2.4 Digital surface model and slope and aspect models 
The HRSC-A images were processed automatically by DLR 
(German Aerospace Center) in the photogrammetric processing 
described by Wewel et al. (2000). This process permits 
production of a digital surface model (DSM) of the imaged area. 
Two raster models for both test sites were produced, one per 
flight session, with a one-metre cell size. The height resolution 
of these models was five centimetres. The slope and aspect 
raster images were calculated to characterise the surface 
slanting and derive a surface normal for each pixel. The spatial 
resolution of these models was one metre. 
2.5 Sun angle data 
The sun angles at the time of image acquisition were determined 
using time averages for each image strip. A feasibility point 
near the crossings of the flight strips at both test sites was used. 
At the Sjókulla test site, the feasibility point was located at 60? 
14' 31.07"N, 24? 23' 3.00" E. In Kuckuberg, the corresponding 
point was located at 60° 12° 30°°N, 24° 27’ 00" E. 
Sun angles were calculated at one-minute intervals. Angles for 
the full minute nearest to the average time of an image strip 
were chosen. The rounding causes some error in the sun 
direction at the ends of each image strip, but due to the short 
image acquisition period of a single strip and the even smaller 
intensive test area this does not have a significant effect. The 
estimated azimuth error was 0.30° and the zenith angle error 
0.06° at the ends of each image strip. 
2.6 Ground data 
The test sites were examined for ground truth data at the time of 
the HRSC-A flights. Documentation of the scenes was 
performed by photographing the targets, determining the species 
and defining the areas on to a map. Vegetation and the current 
state of growth were also recorded. 
For sensor calibration, three additional known reference targets 
were spread over the area of the photogrammetric test field, 
which has dark gabro gravel as background. The reflectance 
properties of the reference targets have been determined by 
laboratory calibration tests and they will be used for sensor 
calibration. 
2.7 Sample point determination 
To derive a proper reflectance sample with correct angular 
measures, the image acquisition had to be reconstructed. Using 
the position and attitude data of the camera and single optics 
camera model, any image cell on a CCD line sensor could be 
captured with the known viewing azimuth and zenith angles 
and the corresponding target point on the ground surface. 
» 
An HRSC-A camera has nine parallel CCD line sensors 
mounted with specific measuring angles with an 11.8° swath 
and the location of a sensor cell could be determined using these 
angles. The height reference surface could be reached by means 
of a rotation of the constructed image vector with a 3D rotation 
matrix and by scaling the result 
Mox 
^ 
=MR.R,R,|v|, (2) 
K^ Nw 
N 
N 
where x, y and z are sensor cell coordinates on the image plane 
and the triplet X, Y, Z is a vector from the projection centre of 
the camera to the ground. M is the scale factor. 
The actual sample point (measured by the camera) was 
determined by finding the intersection of the target vector and 
the digital surface model. This was carried out using a bisecting 
algorithm. The search area for the intersection point in the 
direction defined by the direction vector was initialised to begin 
from the maximum height of the surface model and to end at the 
minimum height of the surface model. 
The intersection point lies between these two preset end points. 
The search for the intersection point was carried out bisecting 
the search area, or vector, and checking whether the middle 
point is above or under the surface. If it is above the surface, the 
beginning of the new search area is set. Otherwise, it is set to be 
the end of the search area. Iteration continues until the distance 
between the height surface and iterated point is less than a 
preset threshold. 
The threshold value used in this study was five centimetres, 
which corresponds to the height resolution of the digital surface 
models. For a maximum HRSC-A view zenith angle of 18.9°, 
five centimetres threshold means less than two centimetres 
uncertainty on the horizontal ground plane, which is acceptable 
for even more detailed image resolution. 
The 11.8° opening angle of a single line sensor was divided into 
200 parts, giving an angular separation of 0.059° for adjacent 
samples. This corresponds to a distance of approximately 3 
metres between the sampled data points in a cross-track (i.e. 
sensor) direction from a flight altitude of 3000 metres. In flight 
direction, the sampling interval was approximately 3.5 metres at 
flight a speed of 69 m/s and was attained by linearly 
interpolating the sparse one second interval GPS data and 1/10 
second interval inertia data to a 1/100 second interval dataset 
and picking every fifth point with its position and attitude data 
from the set. Linear densification is considered to have only a 
minor effect on data quality. 
2.8 Geometric measures of BRDF: flat and slanting surfaces 
The BRDF geometry was first investigated for a flat surface. 
The view zenith angle of a sample was calculated simply, using 
the target and zenith vectors. The azimuth of the target vector 
was measured clockwise from the north. Sun angles were 
calculated as described above in caption 2.5 and were applied 
here. The relative azimuth of the viewing and illumination 
directions was calculated. 
Regarding each DSM point as a slanting plane, the BRDF 
coordinates could be determined in relation to the normal vector 
of this plane. The aspect value was corrected for meridian 
convergence and the normal » was constructed out of the 
corresponding slope and aspect values of the sampled object 
point. Sun and viewing vectors § and ¢ were constructed 
using the corresponding zenith and azimuth values (64, 0,9 and 
OQ, $5) Viewing and illumination zenith angles @. and 6, 
relative to the surface normal were then calculated. 
     
   
  
   
   
   
    
   
    
  
    
     
   
   
    
  
  
  
  
   
   
    
     
      
   
   
    
   
    
   
   
   
  
    
    
   
   
   
   
   
   
    
   
    
   
    
  
     
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