For monitoring bioproduction in the lakes, information 
were first assessed separately for each scene using 
the index ‘Mean’ (IRS1,IRS2). For this purpose 
summary statistics of the index were calculated based 
on all core lake areas for the individual dates (see 
tab.3). In order to get a better understanding about the 
differences between the lakes in one scene, the 
frequency distribution of the means of all core lake 
areas was analyzed for this index which led to a 
classification of the lakes into equidistant classes. Only 
exception were the minimum and maximum values 
which form two broader classes representing the 
extreme values (see fig.5) These results and the 
comparison between the different dates give a first 
impression of the seasonal behavior of the lakes. 
In a second step the temporal changes between the 
dates were further analyzed by calculation of the 
differences between the values of the index for 
consecutive datasets. Table 4 shows the summary 
statistics of these differences which were also 
classified based on histogram analysis (see fig.6) 
following the same principles as for figure 5. 
Information of all scenes available for the observed 
time were combined to distinguish between lakes of 
similar seasonal behavior. Spatial variations of 
calculated indices within a dataset and variations 
between scenes are caused by differences of lake 
water properties. Thus, the principal component 
analysis (PCA) could be used for assessing these 
differences in a compressed way, because the main 
variation within the data is represented by the first 
principal component (PC). The first PC allows grouping 
the lakes into classes of similar seasonal behavior of 
bioproduction. The input data for the PCA were the 
means (IRS1,IRS2) of all 6 acquired scenes. 
4.4 Results for analysis of individual dates 
The approach is based on the relation between field 
measurements and the spectral properties of the lakes 
and intends to show the relative spatial and temporal 
changes of bioproduction in lakes. Figure 4 shows the 
relationship between ground measurements of 
chlorophyll-a content of the 3 lakes Gr. Wummsee, Gr. 
Zechliner See, Braminsee and calculated indices for 
similar dates (see tab.2). 
  
  
  
  
  
85 T A Braminsee 
e 307 a ô Ó 
9 25 + 
E 20 
2 LS teur ses A Difference (IRS 1, IR S 3) 
= 190 108 OMemn(RS1,IRS3) 
a ; Gr. Wumms ee i 
0 20 40 60 80 100 
Chlorophyll-a concentration in pg/l 
  
  
  
Fig. 4: Relation between calculated indices and 
measured chlorophyll-a for three lakes for comparable 
dates in 1997 (May, June, Sept.,1, Sept.,25) 
It is assumed that the spectral properties of the other 
lakes follow this relationship and can be used for 
relative differentiation of chlorophyll-a content between 
the lakes observed during the whole time. 
Based on relation between the calculated means 
(IRS1,IRS2) and chlorophyll-a content the 
differentiation of high or low chlorophyll-a contents can 
be assessed for all lakes. 
  
  
  
  
  
  
MEAN Aug| Feb 2|May 4| Jun 2| Sep 1 Se 
anstansm I i d B 97 Yor 97 "o7 25 
96 97 
Mean 10,9 6,5 9,9 8,51 11,4 8,7 
Min 32 27 2,8 0,7 2,7 3,9 
Max 24,7| 12,8| 29,55| 29,1] 32,7] 41,3 
Stdev 4,6 2,1 5,3 4.8 6,3 6 
  
  
  
  
  
  
  
  
Tab. 3: Summary statistics for Mean (IRS1,IRS2) of all 
core lake areas for each dataset 
A comparison of the summary statistics of the means 
(IRS1,IRS2) for the different datasets (see tab. 3) 
shows significant differences between the dates. The 
minimum in February corresponds to a low level of 
bioproduction during winter time. The two maxima in 
August and early September are in accordance to 
periods of high bioproduction in summer. The mean 
value for May indicates a first algal bloom in spring. 
The data also show a greater variation between the 
lakes for the same date than for one lake through all 
dates. The lowest variation can be observed in 
February representing the time of minimal 
bioproduction in all lakes. However, all of the other 
dates show high and widely varying values which 
reflect the big range of trophic state conditions in the 
study area. 
  
— $—— Augl8 96 
— —- —Feb02 97 
- - - À- - - Ma/04 97 
—9—— Ju0297 
——3—— S8p01 97 
——68—— $8025 97 
    
  
   
— N 
C1 © 
cp po 
Number of lakes 
S 
  
  
  
Fig. 5: Frequency distribution of Mean (IRS1,IRS2) 
calculated from means of all core lake areas 
4.5 Results of multitemporal analysis 
For characterizing the behavior of lakes in the study 
area the relative changes between different dates (see 
fig.5) were analyzed as well as the absolute amount of 
changes (see fig.6) between dates. 
Fig. 5 shows a significant increase of the number of 
lakes characterized by higher values between February 
and May which continues partly until June, and further 
until the beginning of September. Between May and 
132 International Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
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