between reference DTM and reconstructed DTM. 
While in simulation 2) the difference between 
observed and calculated grey value is due to a 
constant factor, in this simulation the difference is 
caused by a wrong assumption concerning the 
relation between the grey values and the angles i 
and e. It should be noted that in this case a large 
number of iterations had to be performed before a 
convergence was reached. 
- The last group of simulations served to assess, 
whether unknown albedo can be estimated together 
with unknown DTM heights. The DTM heights 
could be successfully reconstructed in all 
experiments. The unknown albedo nearly reached 
the correct value after the first iteration. The 
remaining height offset and surface tilt are then 
removed, until the correct values for the heights and 
the albedo are achieved. In comparison to 
simulation 2), where a wrong albedo caused a tilt of 
the whole surface towards the light source, the grey 
value differences here result in an improvement of 
the albedo in order to remove this tilt. This is due 
to the fact that the albedo is a constant factor, 
which influences all grey value observations in the 
same way. Since this behaviour is independent of the 
difference between correct and initial albedo value, 
all experiments reconstructed the surface heights 
and the albedo after the same (few) number of 
iterations. 
4.4. Conclusions 
Our SFS algorithm has been tested successfully using 
synthetic images. In comparison to the well-known 
Lambert law, the Lommel-Seeliger law was introduced, 
along with unknown surface albedo, as a model for the 
surface reflectance properties. The following 
conclusions can be drawn from the results presented 
above: 
- The Lambert law turns out to be unstable, resulting 
in singularities for the surface reconstruction, if 
multiple images with identical illumination direction 
are introduced. This behaviour is independent of the 
exterior orientation of the images, since the image 
grey values are not influenced by the camera 
position; 
- The Lommel-Seeliger law allows for a correct 
surface reconstruction, even if all images are 
introduced with identical illumination direction. The 
image grey values are a function of camera position, 
and therefore additional independent information is 
available for the surface reconstruction; 
- SFS using the Lommel-Seeliger law is a method to 
reconstruct unknown heights correctly, even if poor 
initial values, e.g. a horizontal plane, are introduced, 
- Unknown albedo can be estimated correctly from 
the images, along with unknown heights, even if an 
extremely wrong initial albedo value is introduced; 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996 
this is due to the fact that the initial value for the 
albedo affects all grey value observations in the 
same way. 
- Wrong albedo introduced as error-free results in an 
incorrect inclination of the whole surface relative to 
the illumination direction. The relative height 
differences within the surface, however, can be 
reconstructed with high accuracy; 
- If the imaged surface does not obey the modeled 
reflectance behaviour, completely wrong heights are 
obtained. In contrast to a surface reconstruction 
with wrong albedo, the resulting height differences 
are also a function of the surface topography. 
Therefore, SFS can only produce correct results, if 
the reflectance properties of the surface are modeled 
appropriately. 
5. OUTLOOK 
Multi-image SFS using the  Lommel-Seeliger 
photometric function turned out to yield good results, 
even if poor initial values for the unknown surface 
parameters are available only. Additionally, this 
approach can overcome singularities which occur when 
Lambert surfaces have to be reconstructed from 
multiple images with identical illumination direction. 
However, only synthetic images have been used; 
therefore, the presented approach has to be tested 
using real imagery of poorly textured surfaces, such as 
planets or asteroids, in order to evaluate the 
correctness of the surface reflectance model, and to 
assess the robustness and reliability of the methods 
when image noise and non-uniform albedo are 
present. Furthermore, the demands of the MARS96 
mission have to be met by implementing the three-line 
scanner imaging geometry of the HRSC and WAOSS 
sensors. 
6. REFERENCES 
Albertz J., Scholten F., Ebner H., Heipke C., Neukum G. 
(1993): Two Camera Experiments on the Mars 94/96 
Mission. GIS 6 (4), 11-16 
Hapke B. (1981): Bidirectional Reflectance 
Spectroscopy; 1. Theory. Journal of Geophysical 
Research 86 (B4), 3039-3054 
Hapke B. (1984): Bidirectional  Reflectance 
Spectroscopy; 3. Correction for Macroscopic 
Roughness. Icarus 59, 41-59 
Hapke B. (1986): Bidirectional Reflectance 
Spectroscopy; 4. Extinction and the Opposition Effect. 
Icarus 67, 264-280 
650 
     
  
  
  
  
  
  
  
  
  
  
   
   
  
  
  
  
   
  
  
  
   
   
   
  
   
  
  
  
  
   
  
  
  
   
  
   
  
   
   
  
  
  
   
  
  
  
  
   
  
  
   
  
  
  
   
  
   
   
Spec 
Heip 
Matc 
Musi 
S.J. 
Berli 
Heip 
Recc 
Shad 
Horn 
Horn 
Shad 
Lum 
Surf: 
Astr 
McE 
Phot 
298-: 
Minn 
Lunz