al 
in 
ot 
ct 
ts 
li- 
>t- 
on 
r= 
    
mined. (Table 3.) 
Mean positional error in 
  
  
  
Ortophotomaps Kdentical metsts 
points 
TER TRY HUC 
Pre-war 23 1,20 1,34 1,32 
Post-war 100 1,30 1,76 1,54 
  
  
  
  
  
  
  
  
Table 3. Mean positional error in meters 
3. RESULTS AND DISCUSSION 
3.1 Changes in the riverbed and humidity conditions 
Investigated area is lowland and in the past river Satava created 
meanders. The river was straightened later and agricultural cul- 
tivated area increased. Soils in the original river bed and the wa- 
terlogged area have different physical and chemical properties. 
The present Land Use are limited by different soil properties. 
Remote sensing in the near-infrared band shows the historic 
riverbed and waterlogged areas (Figure 4.) 
    
| Figure 4. Historic riverbed 
3.2 Changes in forest area 
The whole area was forested in the ancient past. After the arri- 
val of a man began deforestation. The process of afforestation 
or deforestation of small areas continues today. They form a 
compact forest units and have removed the small forest area. 
Deforested areas have different properties. Therefore, we can 
see the different areas in the near-infrared band. (Figure 5.) 
  
Figure 5. Deforested area 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
3.3 Sand excavation 
Specifics of the area are locations where sand has been excavat- 
ed. At first sand removed from the location, where farming had 
taken place, and subsequently the remaining pit was filled with 
sludge from the nearby sugar refinery in Zidlochovice, with the 
land then forested via volunteer seeding. When the area of ara- 
ble land was increased in the 1970s, that land came under culti- 
vation and was not reclaimed. Although it is used for agricul- 
tural purposes today, under adverse moisture conditions 
cultivation is not possible. Any other use is therefore practically 
impossible. The entire process has taken place without clear 
ownership relations. (Figure 6.) 
    
Figure 6. Sand excavation 
4. CONCLUSIONS 
Aerial photos in the near-infrared band well identify changes 
that are caused by different Land Cover earlier. Finding the 
origin of these differences in historical materials to determine 
the limits of today's recovery and prevent unsuitable Land Use. 
This procedure is suitable as a background document for devel- 
opment of regional plans and design of the land consolidation. 
REFERENCES 
Ferwerda, J. G., Skidmore, A. K. & Mutanga, O., 2005. 
Nitrogen detection with hyperspactral normalized ratio indices 
across multiple plant species. International Journal of Remote 
Sensing, 26 (18), p. 4083-4095. 
Gojda, M., 2000 Archeologie krajiny. Academia, Praha, 240 p. 
Haboudane, D., Miller, J. R., Patey, E., Zarco-Tejada, P. J. & 
Strachan, I. B., 2004. Hypespaktral vegetation indices and novel 
algorihms for predicting green LAI of crop canopies: Modeling 
and validation in the context of precison agriculture. Remote 
Sensing of Environment, 90, p. 337 — 352. 
Kube&, J, 1996 Plánováni venkovské krajiny. MZP, Praha, 
186 p. 
Lipsky, Z., 1999 Krajinná ekologie. Karolinum, Praha, 129 p. 
Reyniers, M., Vrindts, E. & DE Baerdemaeker, J., 2006. 
Comparison of an aerial-based systém and an on the ground 
continuous measuring device to predict yield of winter wheat. 
European Journal of Agronomy, vol. 24, no. 2, p. 87-94.