Na
nd the
dra-
stones
merged to obtain meaningful areas (eg road areas). The
merging can be constrained by relations of the topo-
graphic objects (eg roads build up a network) that are
denoted by the areas.
6. OUTLOOK
A model and its representation for the interpretation of
large-scale maps and first results for the interpretation
of a cadastral map were presented.
One of our major goals is the determination of the
topographic objects. Support can be gained from the
following principles that describe relations between
topographic objects. Together with the topographic ob-
jects these principles can also be used for the analysis of
aerial images.
The first principle is based on a relation between the type
of basic objects that can be regarded as areas and their
functionality: Basic objects that together build up a "mo-
saic of areas” (eg building, meadow, field) and basic
objects that build up one or more "networks of long
areas" (eg road, railway, waterbody). Based on this dis-
tinction relations exist between the objects building up
the network of long areas on the one hand and the types
of networks (eg rivers naturally build tree-like networks,
roads build networks with a hierarchy according to the
road types) and the types of the crossings (eg rivers cross
railways and roads only by overpasses or underpasses)
on the other hand.
The second principle is that there exist relations between
parts of the network of long areas and some kinds of
objects (eg parking spaces are connected with the road
network).
The third principle deals with objects in the network of
long areas. These objects are often accompanied by
different parallel objects (eg traffic lanes and pavement
track).
The fourth principle is concerned with objects from the
image mosaic. Their forms are related to their type
(areas like buildings have well defined forms). The
orientation of an object is related to the orientation of
other objects (eg a house is often oriented parallel to a
road).
The fifth principle is a physical exclusion relation of
some kinds of objects on some objects that can be regar-
ded as areas (eg a pylon is not allowed to be placed on a
highway).
585
7. REFERENCES
Antoine, D. (1991): CIPLAN: A Model-Based System
with Original Features for Understanding French
Plats. Proc., ICDAR '91, First Intern. Conf. on Docu-
ment Analysis and Recognition, Saint Malo, pp. 647-
655.
Domogalla, U. (1984): Ein Expertensystem für die auto-
matische Erfassung von technischer Graphik. Proc.
DAGM/OEAGM, pp. 297-303.
Ilg, M. (1990): Knowledge-Based Interpretation of
Road Maps. Proc. 4th Int'l Symposium on Spatial
Data Handling, Zürich, pp. 25-34.
Illert, A. (1991): Automatic Digitization of Large Scale
Maps. 1991 ACSM-ASPRS, Vol. 6, Auto Carto 10,
Baltimore, pp.113-122.
Joseph, S.H. (1989): Processing of Engineering Line
Drawings for Automatic Input to CAD. Pattern Re-
cognition, Vol. 22, No. 1, pp. 1-11.
Kilpeláinen, T. (1988): Automatic Objects Recognition
in Line Maps. Int. Arch Photogr. RS, Part B10/IV,
pp. 327-336.
Maderlechner, G. Jeppson, O. (1988): Representation,
Classification and Modelling of Graphs for Efficient
Pattern Recognition in Line Images. 9'th Int. Conf.
on Pattern Recognition, Rome, pp. 678-680.
Mulder, J.A. (1988): Discrimination Vision. CVGIP 43,
pp. 313-336.
Niemann, H., Sagerer, G.F., Schróder, S., Kummert, F.
(1990): ERNEST: A Semantic Network System for
Pattern Understanding. IEEE T-PAMI, Vol. 12, No.
9, pp. 883-905.
Schmitz, W. (1991): Automation der Katasterkarten
mittels Scanner und Mustererkennung. In: Geo-In-
formatik, Schilcher (ed.), Siemens, pp. 181-186.
Smith , R.W. (1987): Computer Processing of Line Im-
ages: A Survey. Pattern Recognition, Vol. 20, No. 1,
pp. 7-15.
Suzuki, S., Yamada, T. (1990): MARIS: Map Recog-
nition Input System. Pattern Recognition, Vol 23,
No. 8, pp 919-933.
