d using the. 
After the 
/ha) can be 
nted blobs. 
rmining ‘the 
own can be 
on the angle 
entre of the 
f the trees 
of the tree 
thod, and it 
  
ree species, 
> number of 
, divided by 
separated in 
rees. In the 
st concavity 
n light), the 
eparated. In 
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d. I tried to 
s method is 
/ inside the 
GIS 
to GIS. The 
case of all 
anaged and 
d put to the 
the vectors 
TM - SPOT 
P image, from 1:50000 - 1:15000 is the P1, and from 1:15000 - 
1:500 is the P2. The coniferous-deciduous classification of the 
Pl was compared to the classified Landsat TM. I joined the 
seven classes to these two groups. The crosstabulation matrix are 
shoed in Table 14. 
  
Landsat TM |P1 | coniferous | deciduous 
coniferous 0.98 0.01 
deciduous 0.02 0.96 
  
  
  
  
  
  
  
Table 14: The crosstabulation matrix of Landsat TM and P1. 
Then I made a new attribute to the thematic coverage, called age- 
group, and if it was necessary some polygons were divided, on 
the strength of the P1 classes. The major roads out from P1 was 
vectorised and conversed to an arc coverage experimentally, but 
far wasn't proper. 
The next step was the division of the stands (from the Landsat) 
to part stands on the basis of P2 classification, and some other 
attributes, i.e. unit trunk number/ha, average crown diameter, 
health status, the blend rate were added to the polygon attribute 
table. 
The result is an ArcView project, in which a coverage with the all 
extracted data are presented, with the appropriate raster 
background, and containing the originally available data, i.e. 
NFDB, DFBM, DTM for the analysis’s. 
8. EVALUATIONS OF THE ACHIEVEMENTS 
The results of the Landsat TM’s classification with the 
maximum likelihood algorithm using empirical probability 
density is very promising for forests. Although the determination 
of the classes isn’t an easy task. The general distributions of 
forest stands should be specified (e.g. for Hungary or for 
Europe). A rough DTM determination is possible from the band 
Iv. 
The reclassification of the SPOT P image is a very simple, but 
accurate tool for forest - non-forest separation. The SPOT P 
hardly usable for coniferous - deciduous classification. 
The Brovey-transformed Landsat TM and SPOT P is very 
spectacular, and provides a good background for the vector maps 
in GIS, but (mostly at different date of sources) almost useless 
for classification purposes 
The texture analysis of a 3 m ground resolution images (P1) 
demonstrated that is suitable for age estimation. 
The new way of classification of an 0.5 m ground resolution 
ortho-images (P2) showed, that a lot of forest stands’ parameters 
can be obtained (semi)automatically from images at this scale. 
These items of information are unfortunately still too expensive 
for the forestry practice, but hopefully it would change before 
long. 
9. ACKNOWLEDGEMENT 
I acknowledge the data, the software and the support from the 
DigiTerra Engineering Office, the data from National Forestry 
Service (AESZ), and from the Mapping Office of the Hungarian 
Army (MH TEHI). 
10. REFERENCES 
Baskent, E. Wardayo, W., 1997. The Integrated Use of 
Geographic Information Systems and Remote Sensing in Forest 
Ecosystems Management. In: International Workshop, 
Application of Remote Sensing in European Forest Monitoring; 
Proceedings Vienna, Austria, pp. 115-121. 
Czimber, K. - Markus, 1., 1997. Mapping and Monitoring the 
Forested Area Applying Remote Sensing and GIS. In: Archives 
of Earthphoto Seminar, Budapest, 1997.03.12-13. pp. 104-106. 
Eckstein, W., 1996. Segmentation and Texture Analysis. In: 
International Archives of Photogrammetry and Remote Sensing, 
Vienna, Austria, Vol. XXXI., Part B3, pp. 165-175. 
Hocevar M., Kovac N., Kobler K. (1997): Application of Remote 
Sensing and GIS from Landscape to Forest Stand Level. In: 
International Workshop, Application of Remote Sensing in 
European Forest Monitoring; Proceedings Vienna, Austria, pp. 
33-45. 
Hyyppä J., Inkinen M., Hyyppa H. (1997): Applying Multi- 
Source Remote Sensing Data for Forest Inventory. In: 
International Workshop, Application of Remote Sensing in 
European Forest Monitoring; Proceedings Vienna, Austria, pp. 
69-77. 
Király, G., 1997. Large-scale Forest Inventory by Means of 
Digital Images. Thesis work, University of Sopron. 
Koch B., Fritz R, Kremmers Th. (1997): Possibilities to 
Integrate High Resolution Satellite Data in Forest Inventories. In: 
International Workshop, Application of Remote Sensing in 
European Forest Monitoring; Proceedings Vienna, Austria, pp. 
27-32. 
Laws, K. 1980. Texture Image Segmentation. PhD. Dissertation, 
Dept. of Engineering, University of Southern California. 
Lohmann, G., 1994. Co-occurance-based analysis and synthesis 
of textures. In: 12 International Conference on Pattern 
Recognition, pp. 449-453. 
Markus, 1, (Ed) 1995. PHARE MERA Forest Ecosystems 
Mapping, Final Report, Sopron. 
Narendra, P.M., Goldberg, M., 1980. Image segmentation with 
directed trees. IEEE Transaction on Pattern Analysis and 
Machine Intelligence, vol. PAMI-2, no. 2, pp. 185-191. 
Shao, J., Förstner, W., 1994. Gabor Wavelets for Texture Edge 
Extraction. In: International Archives of Photogrammetry and 
Remote Sensing, Vol. XXX., Part 3/2, pp. 745-752. 
Turner, M. G., 1989. Landscape Ecology: The Effect of Pattern 
on Process. Annu. Rev. Ecol. Syst., 20, pp. 171-197. 
Zhu, C., 1996. Remote Sensing Image Texture Analysis and 
Classification with Wavelet Transform. In: International 
Archives of Photogrammetry and Remote Sensing, Vienna, 
Austria, Volume XXXI., Part B3, pp. 1036-1038. 
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 369