ISPRS Commission III, Vol.34, Part 3A „Photogrammetric Computer Vision“, Graz, 2002
The assessment of the results was performed by comparison of
the results of the automatic interpretation, as described in this
paper, and a manually created biotope mapping for the last
epoch 1998. Two points were included into the comparison: the
segment borders and the classification of the segments. The
segment borders were in most cases similar, as well as the
classes. Following differences could be found: Some areas,
which were manually classified as “forest”, were assigned to
“area of regeneration birch state” by the automatic system.
Also, the opposite case could be found. The reason is that there
is no sharp separation between transition of these two classes.
The question, when the class “area of regeneration birch state”
ends and when the class “forest” begins is more or less
subjective.
In some other areas the automatic system classified “area of
regeneration” as “area of degeneration”. The reason is that both
classes look very similar. The assignment to one of these
classes can only be done by using temporal history of the
segments (see above). For the misclassified cases the automatic
system did not have enough temporal information for the
epochs before 1975. The use of images from epochs before
1975 would probably lead to correct results in those segments.
8. CONCLUSION
A system for knowledge based multitemporal interpretation of
aerial images was presented. The explicit knowledge
representation allows an easy integration of expert knowledge
into the system. For interpretation of vegetation areas the
concept of manual interpretation by using interpretation keys
was transformed into an automatic interpretation system by
using feature analysis operators. For interpretation of temporal
changes an approach was presented, which discretely describes
temporal conditions of regions, and which transfers the most
probable temporal changes of the given conditions as temporal
knowledge into a state transition diagram, then using it for
multitemporal interpretation.
Based on these approaches a procedure for automatic
multitemporal interpretation of industrially used moorland was
successfully developed. Proceeding from an initial
segmentation based on Geo-Data resegmentation and
interpretation of the segments is carried out for each
investigated epoch. By using temporal knowledge it is possible
to separate moor classes, which can only be detected in
temporal order. The application of temporal knowledge and
structural features enables the exclusive use of greyscale images
for interpretation of vegetation areas. The results show that the
presented procedure is suitable for multitemporal interpretation
of moorland, and that it is able to distinguish additional moor
classes compared to the approaches used so far. It is further
applicable for a more robust multitemporal interpretation, and
does not depend on colour images.
In some parts this work contains potential for improvements.
Although the feature analysis operators are designed to work
with a minimum of parameters, their automatic adaption to the
used images would improve the system's level of automation.
Further parts are resegmentation and probabilities of
multitemporal interpretation. Additionally, the suitability of the
used prior knowledge should be verified for other moor areas
and other applications.
9. REFERENCES
Eigner, J, Schmatzle, E, 1991. Handbuch des
Hochmoorschutzes - Bedeutung, Pflege, Entwicklung. Kilda-
Verlag, Greven, 158 p.
Forstner, W., Liedtke, C.-E., Biickner, J. (Eds.), 1999.
Workshop on Semantic Modelling for the Acquisition of
Topographic Information from Images and Maps (SMATI'99).
Proceedings, Bonn, 227 p.
Growe, S., 2001. Wissensbasierte Interpretation
multitemporaler Luftbilder. Dissertation, Universität Hannover,
Fortschritt-Berichte VDI, Reihe 10, Nr. 656, VDI-Verlag,
Düsseldorf, 144 p.
Heipke, C., Pakzad, K., Straub, B.-M., 2000. Image Analysis
for GIS Data Acquisition. Photogrammetric Record, 16(96),
pp. 963-985.
Liedtke, C.-E., Bückner, J., Grau, O., Growe, S., and Tónjes,
R. 1997. AIDA: A system for the knowledge based
interpretation of remote sensing data. 3rd. Int. Airborne Remote
Sensing Conference and Exhibition, Vol. II: pp. 313-320.
Lunetta, R. S., Elvidge, C. D. (Editors), 1999. Remote Sensing
Change Detection — Environmental Monitoring Methods and
Applications. Taylor & Francis, London, 318 p.
Mayer, H., 1998. Automatische Objektextraktion aus digitalen
Luftbildern. Deutsche Geod. Kommission, Reihe C, Nr. 494,
132 p.
Niemann, H., Sagerer, G., Schróder, S. and Kummert, F., 1990.
ERNEST: a semantic network system for pattern understanding.
IEEE Transactions on Pattern Analysis and Machine
Intelligence, 12(9), pp. 883-905.
Pakzad, K., 2001. Wissensbasierte Interpretation von
Vegetationsflächen aus multitemporalen Fernerkundungsdaten.
DGK, Reihe C, Dissertationen, Nr. 543, München, 104 p.
Pakzad, K., Growe, S., Heipke, C., Liedtke, C.-E., 2001.
Multitemporale Luftbildinterpretation: Strategie und
Anwendung. Künstliche Intelligenz, (15) 4, pp. 10-16.
Peled, A., Haj-Yehia, B., 1998. Toward automatic updating of
the Israeli National GIS - Phase II. International Archives of
Photogrammetry and Remote Sensing, Vol. 32, Part 4, Stuttgart,
pp. 467.
Tónjes, R., 1999. Wissensbasierte Interpretation und 3D-
Rekonstruktion von Landschaftsszenen aus Luftbildern.
Dissertation, Universität Hannover, Fortschritt-Berichte VDI,
Reihe 10, Nr. 575, VDI-Verlag, Düsseldorf, 117 p.
Von Drachenfels, O., 1994. Kartierschlüssel für Biotoptypen in
Niedersachsen. Naturschutz und Landschaftspflege in
Niedersachsen, Niedersüchsisches Landesamt für Okologie,
192 p.
Weismiller, R. A., Kristoof, S. J., Scholz, D. K., Anuta, P. E.,
Momen, S. A, 1977. Change Detection in Coastal Zone
Environments. Photogrammetric Engineering and Remote
Sensing, 43, pp. 1533-1539.
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