The coordinate system 
he same point was used 
1 between historical (c) 
5), 
images from historical 
g a contemporary DTM 
historical images. 
geometrically correct 
images can be done by 
(Luman et al, 1997; 
an lead to inaccurate 
up to a few meters); 
g landscape changes at 
ying land use changes 
rban areas). 
ion information 
it was necessary to use 
alibration information. 
reconnaissance aircraft 
(Redweik et al., 2009). 
d forms of the fiducial 
at was 9x9 inches and 
fiducial marks consist 
mage sides and appear 
r half-arrows indicates 
). This reconnaissance 
oblique aerial photos 
etrogon lens of 6", 12" 
y 
cal photographs, high- 
"itizing the hardcopies 
1 a suitable calibration 
successfully used for 
hophoto production 
4). For our task, the 
rer was employed. To 
he imagery, the prints 
ution (i.e., 16 micron 
ition. To evaluate and 
ced by the scanning 
both digital (scanned 
rdcopy (contact print) 
  
  
  
  
  
Location | N°. of | Mean Mean Expected | Computed | Expected | Computed | Sigma- | XY-RMSE Z-RMSE 
images | flying base XY XY Z Z naught | on check- on check- 
height distance | precision | precision | precision | precision points points 
Trento 6 8000m | 1000m | 0.8m 2.5m 6m 13m 6.5px | 235m 10m 
2 7550m | 1200m | 0.8m 1.7m 5m 7m sopx |2m 7m 
Rovereto 5 7550m | 1300m | 0.8 m 1.8m 5m 12m 69px | 3m 9m 
  
  
  
  
  
  
  
  
  
  
  
Table 2: Results of acro-triangulation of historical images. 
The print was digitized with the Epson Expression 1640XL 
scanner and then rectified with respect to a softcopy reference 
image applying a second order polynomial function. A final 
RMSE of 1.25 pixel (i.e., 18.75 microns) was obtained and all 
the scanned historical images were then rectified using the same 
estimated polynomial correction. 
3.3 Collecting 4D ground control points 
As mentioned, GCPs are necessary to determine approximate 
interior parameters of the historical images, e.g., by means of a 
Direct Linear Transformation DLT approach (Abdel-Aziz & 
Karara, 1971), and for the image triangulation phase with a 
bundle block adjustment. The identification of reference points 
visible in both the historical and more recent aerial images can 
be very difficult, and thus often inaccurate and unreliable. Two 
problems that commonly affect point or feature identification 
are landscape changes and the low radiometry and resolution of 
historical data (Fig. 3c and Fig. 3d). The least expensive 
solution is the use of geo-referenced maps or orthoimages to 
derive planimetric coordinates and DSM or trigonometric fix 
points for altimetric coordinates (Redecker, 2008). The more 
rigorous and reliable method consists in collecting GCPs that 
are also identifiable in the historical images. In this project, a 
hybrid method was used. GCPs were measured using 
topographic surveying methods, collecting 20 object points 
located primarily on roofs of historical buildings or edges of 
monuments. To analyse the accuracy of the results, some 
checkpoints were identified using the current available DSM. 
3.4 Recovering the interior orientation of the images 
For the transformation between pixel and photo coordinates, a 
virtual coordinate system for the interior orientation was 
constructed. This was accomplished by measuring the four 
fiducial marks visible on a scanned image selected as reference, 
assuming the geometrical centre of the marks as principle point 
and origin of the coordinate system (Fig. 3b). The coordinates 
of the fiducial marks with respect to the chosen principal point 
were then used to compute the six-parameter affine 
transformation for each digitized historical image. Moreover, 
the same sensor format was ensured for all the scanned images 
by cropping of a fixed image size with the principal point at its 
centre. Then the DLT method was applied for assessing the 
most likely nominal focal length for the flights over Trento and 
Rovereto. The results confirmed that both flights were 
performed with a 24" (609.6mm) focal length lens, as 
previously assumed. 
3.5 Recovering the exterior orientation of the image block 
The block geometry of images does not guarantee a strong 
camera network configuration. In this project, there was a non- 
optimal block configuration because the photos came from a 
single flight strip (no sidelap), sometimes with less than 60% 
overlap between successive photos (Fig. 2). Moreover the use 
of a tele-lens resulted in very low intersecting angles between 
85 
optical rays ranging in average from 10 degrees (for stereo- 
images) to 16 degrees (considering three intersecting image 
rays). Other researchers have shown that despite a non-optimal 
block configuration, incorporating additional parameters in 
triangulation can help to account for unknown geometric errors 
caused mainly by the lens but also by other non-modelled 
distortions (e.g, age, maintenance conditions, scanning) 
(Redecker, 2008; Redweik et al., 2009). Based on this previous 
work, the image orientation was performed with a standard 
bundle block adjustment; however, only the exterior parameters 
were solved, because the adjusted values of the interior 
parameters were not statistically significant. The results of the 
aero-triangulation are shown in Table 2. The expected precision 
was calculated considering that the actual measurement 
precision of the imagery (i.e., possibility of resolving details 
and visible features, Fig. 3 c and d) is about 3-5 pixels). 
Incorporating additional parameters (radial and tangential 
distortions) did not produce meaningful improvements in terms 
of residuals on the checkpoints. 
3.6 DSM generation, ortho-rectification and mosaicking 
Once the image blocks were oriented, the DSMs for Trento and 
Rovereto were automatically extracted using image matching 
algorithms. Different algorithms were tested, commercial and 
open-source. To obtain a satisfying compromise between 
smoothing effect and signal to noise relation, typical windows 
of 21 x 21 pixels in rural regions and 13 x 13 pixels in urban 
areas were used. As expected, the resultant surface models had 
some deformations and spikes. In order to improve the quality 
of the DSM, some manual editing was necessary. 
To ortho-rectify and mosaic the two sets of historical images 
(one for Trento and the other for Roverto), the strict 
photogrammetric procedure was applied. Despite some model 
distortions, the historical orthoimages overlaid on the more 
recent orthoimages with a maximum discrepancy of few meters, 
in particular in correspondence of relevant landscape 
discontinuities. Historical orthoimages were also generated 
using the current DTM. The differences between the images 
obtained with the two different elevation models (one generated 
using the historical images and the other generated from modern 
DTM) were not noticeable. 
4. ANALYSES OF LANDSCAPE CHANGES 
To identify landscape changes, it is first necessary to identify 
some features and areas of interest. Normally in urban 
environments, these features are buildings, roads and 
vegetation. Manual image interpretation techniques are always 
more reliable although time consuming. Automatic or semi- 
automatic techniques are desirable although the radiometric 
quality of historical images is often not satisfactory for such 
approaches. The orthoimages generated from the 
reconnaissance aerial photos (WWII) were compared to the 
orthoimages dating back to the 1970s and 2000s in order to 
reveal changes in landscape and urban expansion that has 
occurred over the past 60 years.