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1 electro 
The photogrammetry'!remote sensing courses offered are as follows: 
Photo gramme try' / (4 h) Semester 4 
k Photogrammetry II (4 h) Semester 5 
Photogrammetry III (2 h) Semester 6 
Satellite Remote Sensing (2 h) Semester 7 
elementary 
Photogrammetric Projects (S) (4 h) Semester 6 
Photogrammetric Networks (S) (3 h) Semester 7 
Photogrammetric Project Studies (S) (12 h) Semester 7 
Digital Photogrammetry (S) (4 h) Semester 8 
(S) stands for selective. 
s, technical 
Digital photogrammetry is marked here as a selective. However, elements of digital 
photogrammetry are integrated into all other mandatory and selective courses. Therefore, 
even a student who takes only the mandatory courses is exposed to digital 
^formation, 
;rs 
photogrammetry as well. 
It is not meaningful to list the detailed contents of these courses here. Instead, a brief 
content summary is given in the following. 
rface 
• Photogrammetry I : Definitions, sensors, history, applications: photographic image; 
non-photographic sensors; metric camera; fundamentals of analytical photogrammetry 
(I); geometry and measurement of single photographs; stereoscopy and stereoscopic 
measurements; photo flight; orientation of stereomodel; stereoplctters (analogue, 
computer supported, analytical plotters) 
10S/MIS- 
:iplier and 
• Photogrammetry II : Fundamentals of analytical photogrammetry (II), spatial 
intersection/resection, analytical orientation of stereomodel, bundle solution; 
measurement and refinement of image coordinates (image deformations); recent 
-rties and 
), infrared 
developments on analytical plotters (CCD image scanning, image matching, 
superimpositioning, GIS-integration); DTM (data acquisition, processing, 
interpolation, products); aerial triangulation (classification of methods, preparatory 
works, functional and stochastic models) 
ised-arrav 
?d-array, 
:tion and 
• Photogrammetry 111 : Differential rectification, photomaps; standard techniques for 
model- and photo triangulation (system solutions, matrix structures, storage and 
computational problems, control distributions and theoretical accuracy expectations), 
self-calibration, hybrid systems including dynamic GPS, testfield investigations, 
accuracy studies 
interfero- 
• Satellite Remote Sensing : Fundamentals (spectrum, propagation of electromagnetic 
waves, spectral reflection, image characteristics and image quality, image digitisation); 
sensors (passive, active) and satellites; geometrical sensor models; preparation and 
processing of scenes (preprocessing, classification, rectification, registration); ground 
systems and user centres; development of satellite and space remote sensing activities; 
applications (national and international) 
s, remote 
• Photogrammetric Projects : Selection of 2-3 typical projects in cooperation with 
students: execution of projects, practical work, improvement of operational skills, 
gaining of experience. 
excellent « 
cular for 
• Photogrammetric Networks : Estimation model quality (precision, reliability); precision 
and reliability of close-range and aerial neworks; internal and external reliability, 
blunder detection, data-snooping: statistical analysis of results (linear 
hypothesis with full rank and likelihood ratio functions, tests of additional parameters, 
control and checkpoint residuals, deformation analysis, testfield analysis).