dinating workshops. Based on these prerequisites, the applied
synergetic approach consists of the following common Work
Packages (WPs):
(i) Generating individual catchment data bases containing all
remote sensing and GIS coverages for the end users to be used
during the term of the project and afterwards for the operational
catchment management by the end user.
(ii) Identifying parameters and variables of the end user’s models to
be parameterized by means of a sound systems analyses, which
is based on the close cooperation between research partners and
their respective end users.
(iii) Classifying the physiographic properties comprises the
spatial heterogeneity of the test catchments and . makes
use of multitemporal, multispectral and multisensoral
remote sensing techniques. By processing data from
Landsat TM, SPOT, IRS-1C, ERS-2 and JERS-1 with
color composites of optical and microwave data, a
maximum classification accuracy can be achieved. This
approach is of advantage for the selected meso-scale
catchments, particularly for those areas with limited
accessability.
(iv) Delineating Response Units (RUs) by means of GIS overlay
analyses of raster coverages containing topography, soils and
land use information (Fliigel, 1995, 1996):
- Hydrological Response Units (HRUs);
- Erosion Response Units (ERUs);
- Chemical Response Units (CHRUSs).
Further grid cell analyses within the GIS will reveal insight into
their spatial distributed heterogeneity such as connectivity and
neighbourhood required by the end user's models to route water,
sediment or solutes within the river catchments.
(v) Parameterizing end user model parameters and variables by
means of GIS analyses using attribute tables within the GIS
database.
(vi) Validating the parameterization by cost-benefit analyses (cost
of information per km?) and verification of parameters against
both field data and empirical methods.
The synergetic approach applied within the project is not restricted to
make use of remote sensing as a "stand alone" technique but as a
powerful analysing toolset complementary and integrated to those
already existing in water resources management and modelling.
Therefore, the benefit and cost-effectiveness of this toolset can be
demonstrated and evaluated within the context of the integrated water
resources management system applied.
The interrelationships between the IEC components, their respective
climatic regions and the cooperation between RETS and associated
WPs is shown in Figure 2 and especially in Figure 4.
REFERENCES
Flügel, W.-A., 1995. Delineating Hydrological Response Units
(HRUs) by GIS analysis for regional hydrological modelling using
PRMS/MMS in the drainage basin of the River Broel, Germany.
Hydrological processes, 9, pp. 423-436.
Flügel, W.-A., 1996. Hydrological Response Units (HRUs) as
modelling entities for hydrological river basin simulation and their
methodological potential for modelling complex environmental
process systems - Results from the Sieg catchment. Die Erde, 127,
pp. 43-62.
120 International Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998
P^. (f LL) PEN m FS NL
A
las Be OS
