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3. DATA REQUIREMENTS 
It cannot be assumed that an alpine wide monitoring 
approach can rely only on one sensor type due to 
different repetition rates of the satellites and cloud cover 
problems. Therefore, the studies were concentrating both 
on Landsat-TM and SPOT-PAN/XS data. The technical 
specifications of the above mentioned satellite systems 
are well known and described in several standard remote 
sensing manuals. 
A critical point is the selection of appropriate multi- 
tempor .| imagery where special attention has to be drawn 
to the phenological state of the vegetation. This is 
particul..rly true for higher alpine regions which are 
characterised by a short vegetation period. Therefore, 
also meteorological data has to be used to determine the 
optimal acquisition date. 
Ancill 
Apart from ground data which are required as a priori 
reference for the definition of training areas and for the 
validation of the classification and monitoring results, 
digital terrain models (DTM's) are recommended to 
improve the classification accuracy. DTM's are to be used 
as input to the geocoding and the topographic 
normalisation of all image data. It cannot be expected that 
for all parts of the alpine regions DTM's will be available. 
In that case a lower classification accuracy has to be 
accepted which is particularly a problem in areas with a 
rough terrain. 
4. DATA PROCESSING 
The information on environmental changes results on the 
complementary information content of the multitemporal 
source data layers. However, many restrictions on data 
pre-processing have to be taken into consideration for 
practical monitoring applications. These restrictions as 
well as methods of data fusion for change detection 
Studies will be treated. 
An overview of the proposed technical methods is given in 
table 1. The different image processing steps outlined in 
figure 1 are demonstrated and discussed in detail in the 
following sections. 
Table 1: Workflow of the Change Detection System 
  
ORIGINAL IMAGES / DTM 
  
4.1 PARAMETRIC GEOCODING 
Result: Images with mean position accuracy below one 
pixel size 
  
  
— 
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
  
4.2 TOPOGRAPHIC NORMALISATION 
Result: Topographic normalised images suited for 
classification with only one signature set 
  
4.3 IMAGE CALIBRATION - ATMOSPHERIC 
CORRECTION 
Result: Comparable image signatures of multitemporal 
data sets 
  
4.4 GROUND TRUTH AND CLASSIFICATION 
Result: Classification of normalised (4.2) a. calibrated 
(4.3) multitemporal images using solely training areas 
derived from the actual image 
  
4.5 CALCULATION OF CHANGE VECTOR 
Result: Length of change vectors within windows and 
determination of length thresholds for the differentiation 
of real changes and changes which are due to 
insufficiencies in image calibration 
  
4.6 INTERPRETATION OF CHANGES BY MEANS OF 
THE CLASSIFICATION RESULTS 
Result: Assignment of significantly changed areas into 
change categories according to the classified forest 
parameters 
  
  
4.7 VISUAL APPROVAL FOR CRITICAL CHANGE 
CATEGORIES 
Result: Final classification results for each acquisition 
date and for the change categories 
  
  
4.1 Parametric Geocoding 
The investigation has shown that the analysis of 
multitemporal/multisensoral remote sensing data sets can 
only be efficiently done if the data present itself in a 
common geometry. Geocoding of the images therefore 
has to meet extremely strict requirements if the data 
obtained at different acquisition dates with different 
systems are processed multitemporally in one "data 
stack". 
Geocoding of the individual images of such a data set to 
the geometry of a topographic map is the most common 
procedure to accomplish comparability. In general, 
parametric approaches based on sensor specific mapping 
models have been used for geocoding. Achieved 
accuracies lie in the order of one pixel size. However, the 
experience from monitoring applications has shown the 
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