completed projects - selected points were deducted from previ- 
ously produced orthophotographs. For all these points, the em- 
phasis was on the correct interpretation of historical and con- 
temporary images. 
Given that the initial embedded parameters of external orienta- 
tion images were very approximate, it was necessary for easier 
automatic image correlation to measure connecting-identical 
points on each photo, both in all lines and between these lines. 
During this measurement the ground control points were simul- 
taneously identified. During the measurement, the emphasis 
was on the follow-up RMSE of tie and ground control points. 
After measuring the connecting and ground control points, the 
calculation of elements of the exterior orientation of single im- 
ages on the basis of established limits was carried out. The re- 
sults of the calculation were exterior parameters of aerial imag- 
es, root mean square error on the ground control points, the 
resulting sigma and various textual and graphical outputs for 
subsequent analysis of the valuation, including error messages. 
The aim of the AAT analysis was to examine the mean values 
of residual errors of measured connecting points, the number of 
redundant measurements, mean squared errors of the ground 
control points and calculated angular parameters of exterior ori- 
entation. The inspection of the ground control points’ distribu- 
tion in the block was also necessary as well as the number of 
measured and generated connecting points on the individual im- 
ages in strips and between strips by means of graphical software 
tools. Part of this analysis was also the connection and assess- 
ment of the subsequent triangulation blocks characteristics. 
After the AAT calculation analysis the erroneous connecting 
points and ground control points were remeasured. Further- 
more, the new connecting points at critical spots in blocks were 
measured, and if necessary, new ground control points were 
added. Calculation of AAT was considered final, unless the re- 
quired AAT characteristics were achieved. The achieved aver- 
age mean errors in AAT from the individual triangulation 
blocks are listed in the Table 2. 
  
Table 2. The achieved average mean errors in AAT from the 
individual triangulation blocks 
The resulting AAT accuracy is significantly influenced by the 
defined (unknown) parameters of used aerial surveying cameras 
and used ground control points, including their layout. 
For images orthorectification, it was necessary to carry out the 
radiometric correction on individual images - common editing 
of image defects caused by light aberrations of the aerial camera 
lens, ground reflections, field illumination, sun at different an- 
gles, images processing in different seasons and different flight 
parameters. These radiometric corrections were performed by 
dodging in places, where the dark places were lightened and the 
light places darkened, so that the picture has balanced presenta- 
tion of details in shadows and more light-exposed areas. Alt- 
hough a number of steps of radiometric compensation were 
conducted automatically, high personnel effort was devoted to 
these operations. 
For the desired area of digital image processing and orthorecti- 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
   
fication the DTM necessary to transform the image on the real 
terrain was prepared. The elevation accuracy of digital terrain 
model is due to the resulting orthophotomap expected to be in 
resolution of 0.50 meters to 1.5 meters. The basic problem of 
the used DTM was its topicality, because in many places did not 
match the area state during the years of images acquisition. For 
the necessary corrections of the terrain model (updates removal) 
the original technological process was elected leading to the re- 
quired accuracy of the final orthophotomaps. 
After the orthorectification was performed, the visual inspection 
of resketched images was carried out, by which the geometric 
quality was controlled and on the basis of the control points 
wrong places were marked as well as places with image defor- 
mations. In these designated areas the digital terrain model was 
corrected stereoscopically to the state valid on the date of imag- 
es acquisition. 
After the DTM correction a new redraw followed as well as the 
control of corrected places in the manufactured orthophoto- 
maps. 
Selected parts of archival images were defined using seamline. 
These parts were used in the final mosaic. These cutting lines 
were selected according to the appropriate configuration of the 
terrain so the transition between photos was the least distinct. 
After creating all seamlines the individual files with cutting 
lines were assembled, cutting lines were checked for coverage 
of desired space. Control of topology was carried out whether 
each image corresponds to a polygon with one centroid, and 
whether the cutting line had no loose end. 
After finishing the calculation of mosaicking visual control of 
all map sheets was performed for coverage of the desired area 
without visible errors in the image on the resulting mosaic. 
Places with geometric imperfections were marked into a special 
file. Attention was mainly focused on the places where the cut- 
ting lines cross with communications, line buildings and built- 
up areas in general. Furthermore, the routes of especially dis- 
tinctive communications were checked (main roads, railways, 
roads on mounds or in pits); routes of larger rivers or canals and 
places with bridges were marked in case there were some visi- 
ble deformations caused by redrawing technology and other dis- 
torted places caused by the terrain complexity or imperfect 
DTM. During the cleaning process of the orthophotomaps view, 
the individual places on it were scanned and the retouching of 
major dirt was performed (dust, hair). 
If necessary, some places on the orthophotomap were densitely 
aligned, so the total orthophotomap gave compact impression. 
Appendix 1 shows a sample before and after the final treatment. 
The final products of the orthorectification were the individual 
map sheets of orthophotomaps with a resulting resolution 
of 1 m for orthophotomaps from pre-war period and 0.50 m for 
orthophotomaps from the post-war period, in the map sheets 
layout 1:5000 in the S-JTSK coordinate system, compressed 
TIFF format, size from 6 MB to 10 MB with the relevant TFW 
file bearing the data of georeferencing. 
The resulting positional accuracy of the orthophotomaps is di- 
rectly dependent on the AAT accuracy and DTM accuracy. Po- 
sitional accuracy was verified with existing map data by select- 
ing identical points evenly distributed throughout the area on 
both historical and contemporary ortophotomaps. Coordinates 
were checked at these points and the mean error was deter-