contingent upon the provision of clear, 
unambiguous targets in the imagery. Only 
one category of target was found which 
adequately fulfilled these requirements, 
this being the water surface area of 
dams. Even these targets were somewhat 
deficient in that most dams had changing 
water levels and diameters of 30m or 
less, which translates to only. .a- 2-3 
pixel width in the off-nadir imagery. 
Moreover, there was an insufficient 
number of such targets. 
A second category of targets, which were 
Clearly visible in the imagery, were dam 
embankments. Whereas, the centroid of an 
embankment image was usually clear, great 
difficulty was encountered in finding the 
corresponding position. on the ground. 
Errors of a pixel or more could be 
expected in this target point 
correspondence operation and it was not 
always feasible to assess which were 
'poor' targets. A last general category 
of targets comprised road (few), track 
and fence intersections, or more 
correctly in the latter case, 
intersections of graded tracks along 
fencelines. In most cases these presented 
reasonable image targets, but there was 
the complication that the imagery was 
acquired in 1993, with the ground survey 
being carried out in 1994 and 1995. In 
each dry season a program of grading 
occurs in which roads, tracks and 
fencelines are re-graded following wet- 
season damage, not necessarily in exactly 
the same location as in the previous 
year. 
Notwithstanding identification problems, 
about 80 well distributed image- 
identifiable ground control points were 
established. Two GPS campaigns were 
mounted to provide the necessary ground 
truth data. The GPS survey technique 
employed two base stations and roving 
receivers, with an occupation time of 30 
minutes at each point. Processing of the 
data from the 122 baselines observed 
indicated that a  positional accuracy 
(relative) of 10cm had been achieved. 
To help alleviate some of the problems 
with point identification a number of the 
stations were re-occupied in the 1995 
field campaign. Re-observation of these 
points confirmed the quality estimates 
for the GPS survey. A last phase of the 
second campaign was the survey of a 16km 
3-D profile along an image-identifiable 
fenceline via kinematic GPS. This 
heighting profile was established to 
facilitate an evaluation of the precision 
of MOMS-02 DTM extraction. Further 
details of the GPS survey phase are 
provided in Fraser et al (1996). 
The last component in the establishment 
of the Australian testfield comprised the 
image mensuration stage. Multiple image 
coordinate measurements were observed for 
208 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996 
each of the GPS-surveyed ground points. 
In addition to the set of observations 
made in monoscopic mode on an Intergraph 
ImageStation digital photogrammetric 
workstation at The University of 
Melbourne, independent measurements with 
varying levels of image enhancement were 
also made by MOMS-02 research groups in 
Germany and Switzerland. 
Following qualitative analysis, backed up 
by the results of a process of 2-D image- 
to-ground transformation, a subset of 56 
3-ray points and an additional six 2-ray 
points were deemed likely to display 
measurement accuracies at the 1-pixel 
(10um) level or better. The distribution 
of these.points is shown. in. Figure 1. 
Some 40 of the image points were 
estimated to display a standard error of 
better. than 0.5. pixel  in..all . three 
imaging channels, based primarily on 
image quality. In this paper we consider 
two such data sets, one from Melbourne 
(three channels) and one from Dr E. 
Baltsavias of ETH Zurich (forward and aft 
channels only). In the context of the 
target identification problems referred 
to. ut is noteworthy that the RMS 
discrepancy between these two 
independently observed data sets was 0.7 
pixels or 7um, which is a little higher 
than desired. 
3. MATHEMATICAL MODEL 
The functional model adopted for the 
exterior orientation/triangulation is a 
form of the photogrammetric bundle 
adjustment adapted to accommodate the 
geometric conditions of three-line 
imagery (Ebner et al, 1992): 
f R(X =X) + Ry (Y= 1p) + Ry (ZZ) - MAX + My AY + My AZ] 
X= Xp — 
  
R(X = Xy) t RA(Y — Yo) t R(Z — Z9) [M Ax T MAY - M,AZ| 
(1) 
R3QC- X) Ra(' - X) € Ra - Z) - [MAX - MasAY T MsAz] 
va” f i 
  
  
R(X =X) + Q7 X) (Z7 Z) - [MsAX T MAY T Maz] 
Equation 1 expresses the image coordinate 
observations x,y as a function of the 
following parameters: the elements of 
interior orientation: x, yj and f; the 
coordinates X, Y, and Z of the object 
point; the exterior orientation elements 
X77 20,905, Q5; and k, of the HR,- nadir- 
looking lens; and the relative positional 
and orientation elements AX, AY, AZ, Ao, 
Ap, and Ax of the off-nadir sensor line 
with respect to the projection centre of 
the HR lens. The rotation matrix R is 
obtained as the product .of rotation 
matrices M(Ao, Ao, Ax) and D(w,, Pos Ko) - 
In the standard along-track stereo 
imaging mode, without cross strips, self- 
calibration is not possible and thus a 
number of the parameters forming the 
  
  
  
   
    
  
   
   
  
   
  
  
  
  
    
   
   
  
     
   
  
   
  
   
    
  
    
    
   
    
   
  
  
   
    
   
   
     
   
    
     
    
     
      
     
     
    
    
  
   
   
     
   
    
  
   
   
    
   
  
   
     
    
  
     
   
     
  
extend 
determ. 
include 
and th 
Az<For 
channe. 
02/D2 « 
21-45 
six to 
In lord 
collin 
a re-| 
orient: 
polynor 
Quadra! 
stereo 
1989) 
al, 419 
of MO 
polynor 
propos: 
ali, | 
which 
invest: 
elemen 
orient: 
line i 
then m 
of sen: 
intervi 
QOIS. JF 
given 4 
P(1) = 
where