ds 
nds 
r and 
sion, 
high 
ction 
ctual 
ys in 
mote 
>d on 
ation 
à and 
oring 
ze of 
patial 
vhich 
> and 
nsing 
ns in 
rious 
nutes 
titute 
lands 
1994 
The 
land, 
nsive 
t and 
1 cell 
ut 10 
ering 
Land 
DLO, 
matic 
of the 
available geographic land cover information for 
pan-Europe. Four data bases were used: the RIVM 10 
Minutes pan-European Land Use data base, the 
Bartholomew Euromaps CD-ROM, the ESA Digital Forest 
Map (ESA, 1992) and the Digital Chart of the World, 
originating from the US Defence Mapping Agency. The 
classes of the various data bases were either implemented 
directly or used in (conditional) combinations in order to 
obtain an optimal reference map of pan-European land 
cover in terms of accuracy and nomenclature. In this way 
18 different classes of land cover are distinguished. 
Towards European land cover mapping using remote 
sensing there are very interesting approaches, e.g. the visual 
interpretation of Landsat-TM and SPOT-XS hard copies in 
the CORINE land cover project (CORINE, 1993), taking 
texture, pattern and context into account. The scale of this 
land cover data base is 1 : 100,000. However, CORINE 
does not produce an agricultural, but an ecological legend. 
Landsat-TM and SPOT data have, contrary to 
meteorological satellite data, a high spatial resolution and 
therefore it will take a very long time to map the whole of 
e.g. Europe or Russia. Besides, a frequent update is 
impossible. Moreover, the total processing time and the 
expenses would be unacceptable for monitoring purposes. 
So, to monitor the land cover for an extended area like 
Europe or Russia, low resolution satellite data such as 
NOAA-AVHRR data seem to be more suitable. In a pilot 
study Mücher et al. (1994) used NOAA-AVHRR data for 
deriving as main land cover classes at continental scale: 
arable land, grassland, forest, built-up areas and water. 
A major initiative has been the 1 km land cover project of 
the International Geosphere Biosphere Programme's Data 
and Information System (IGBP-DIS). This had the goal of 
collecting, archiving and processing daily NOAA-AVHRR 
data for all terrestrial surfaces and then deriving land cover 
data sets from this archive. As a result, a 1 km global land 
cover product, called DISCover, has been created (IGBP- 
DIS, 1996). The applied land cover classification scheme 
consists of 17 classes. Because the method is based on 
unsupervised classification of monthly NDVI composites 
per continent, the result is more related to an agro- 
climatologic zonation. 
In this paper methods are described to monitor agricultural 
land cover applying multi-sensor remote sensing 
techniques. In this study the land cover classes, which can 
be derived at different scale levels, will be identified. Main 
goal is the improvement of agricultural land use monitoring 
in Russia. A methodology must be developed, based on 
remote sensing, with a much higher accuracy than 
traditional methods. 
This project is performed in the context of a programme for 
Russian-Dutch co-operation in the field of agricultural 
research, aiming at exchange of knowledge and experience 
concerning remote sensing methodologies and satellite 
systems, including also training activities. 
  
   
level 1 NOAA time series 
    
National & Regional 
‚Statistics 
Biophysical 
Ancillary Data 
    
  
  
  
   
    
  
     
  
Major Land Cover Classes Major Landscape Zones 
Agricultural Regions 
level 2 MSU-SK 
Data 
L Cra lia A 
Delineation of 
Agricultural Areas 
Grassland/Cropland 
    
  
  
  
  
  
  
  
level 3 SPOT, MSU-E, 
Landsat-TM Data 0 
"RTT SUE. 
level 4 | TK-350, 
| KVR-1000 Data Fem 
L——————— 
  
  
  
  
  
Crop Types 
  
  
  
  
  
  
Specific Small Land Cover Types 
and 
Local Phenomena 
  
  
  
Figure 1. Schematic overview of the methodology. 
2. METHODOLOGY 
Figure ] presents a schematic overview of the multiscale 
methodology proposed in this study. First of all, ancillary 
data on soil, altitude, climate, etcetera, in combination with 
statistical data are used for deriving the major landscape 
zones. Then, a multi-temporal selection of coarse resolution 
images (e.g., NOAA-AVHRR) is made depending on the 
sowing and harvesting schemes of a region. These images 
are then classified into the major land cover classes (level 
1) using the stratification of the whole area into the major 
landscape zones (Addink, 1997). This yields the major 
agricultural regions. 
The resulting classes 'arable land' and 'grassland' are 
subsequently checked, delineated more accurately and, if 
possible, further differentiated using medium resolution 
satellite data (around 200 m spatial resolution; level 2). 
Such data (e.g; MSU-SK data) will also facilitate the 
comparison of derived land cover classes from coarse 
resolution and high resolution images. 
As a next step, the pixels classified as arable land or 
grassland, the so-called agricultural pixels, are classified 
according to a more detailed legend (level 3) using high 
resolution images (e.g., SPOT, MSU-E, Landsat-TM). The 
contents of this legend depend naturally on the crops. 
present in the region. Since it is unfeasible to cover the 
entire Russian territory with high resolution images a few 
test sites are studied in more detail. The selection criteria 
for these sites are the percentage of agricultural pixels, the 
availability of ground truth data and the available imagery. 
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 97