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Warsaw University of Technology. APPLICATION OF COMPUTATIONAL INTELLIGENCE ALGORITHMS IN TOPOLOGY PRESERVING PROCESS OF DTM SIMPLIFICATION. Robert Olszewski. A ssumption data. - PowerPoint PPT Presentation
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APPLICATION OF COMPUTATIONAL
INTELLIGENCE ALGORITHMS
IN TOPOLOGY PRESERVING
PROCESS OF DTM SIMPLIFICATION
Warsaw University of Technology
Robert Olszewski
Assumption data
Generalisation of the digital terrain model is an important issue for supplying geographic information systems with data,
The main idea of generalisation of the DTM should be the preservation of its structure (the morphological skeleton),
Simple algorithms of the DTM generalisation allow for relatively low reduction of the structure complexity
The aim of the research
Development of the concept of the multiscale (hierarchical) representation of the terrain relief,
The concept of multirepresentation digital terrain model is a logical supplement of the idea of multirepresentation (MRDB) topographic database and allows to perform common analyses of all topographic components.
Hierarchical DTM with monoscales representations of the model at an arbitrary, user-defined level of generalisation
Distinction:
model generalisation (analysis-oriented), cartographic generalisation (display-oriented)
Spatial data generalisation
Distinction:
DLM (to supply geographic information systems), DCM (to supply maps production systems)
Digital Terrain Model - DTM
Generalisation of the DTM is based on one of the methods (Weibel, 1992):
global filtration,
local filtration (usually multi-stage),
heuristic approach.
Generalisation of the DTM (TIN) is understood as model generalisation and not as generalisation of contour lines
The idea of DTM generalisation
combination of two approaches (local weighted filtration & structure lines extraction), multi iteration approach, determination of the „skeleton” of the terrain, dichotomic classification of source data (mass points vs. structural points), differential weighting for mass and structural points, multiscale (hierarchical) TIN model (with monoscale representations), topology preservation...
The idea of DTM generalisation
combination of two approaches (local weighted filtration & structure lines extraction), multi iteration approach, determination of the „skeleton” of the terrain, dichotomic classification of source data (mass points vs. structural points), differential weighting for mass and structural points, multiscale (hierarchical) TIN model (with monoscale representations), topology preservation...
Tatra Mountains
The idea of DTM generalisation
combination of two approaches (local weighted filtration & structure lines extraction), multi iteration approach, determination of the „skeleton” of the terrain, dichotomic classification of source data (mass points vs. structural points), differential weighting for mass and structural points, multiscale (hierarchical) TIN model building (with monoscale representations), topology preservation...
drainridge
Topology preservation
Spatial data mining and model generalisation
Nowadays, the algorithmic approach may be considered as the dominating tendency in the field of spatial data generalisation, but…
Results of utilisation of computational intelligence and cognitive modelling are also very promising ...
On the contrary to classical expert systems, well known since the eighties of the 20th century, which utilise IF-THEN deterministic rules, the essence of this approach is connected with the use of machine learning (ML) processes (Meng, 1998).
Inference systems
Inference „engines”:
CRISP
FUZZY
NEURO
The idea of DTM generalisation
combination of two approaches (local weighted filtration & structure lines extraction), multi iteration approach, determination of the „skeleton” of the terrain, dichotomic classification of source data (mass points vs. structural points), differential weighting for mass and structural points, multiscale (hierarchical) TIN model (with monoscale representations), topology preservation...
Weighted local filtration
In the process of generalisation points are eliminated basing on local evaluation of several criteria: vertical significance (mass points & structural points),
horizontal significance (density) (mass points & structural points),
the weight of a structural line (structural points only),
the local sinusoity of a structural line (structural points only).
Selection of significance of particular factors is fully parameterised, what allows arbitrary assigning of
weighting coefficients.
DTM generalisation
TIN generalisation
Implementation
2D (MapInfo)
3D (ArcGIS)
Hierarchical model
Levels of TIN
1st level
2nd level
3rd level
topology preservation
Inference engines Engines already implemented:
CRISP, FUZZY, NEURO
Engines to be implemented:
classification and regression trees, boosted trees, „random forest”, MARS (Multivariate Adaptive Regression Splines), SVM (Support Vector Machines)
Conclusions
The basic feature of generalisation of the terrain model should be the preservation of its structure (the morphological skeleton) - topology preservation,
Utilisation of local weighted filtration algorithms allow for :
representative selection of points from the source model,
the construction of the multiscale (hierarchical) TIN model with a monoscale representation at an arbitrary, user-defined level of generalisation,
topology preservation..
