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Some computational aspects of geoinformatics

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Title: Some computational aspects of geoinformatics


1
Some computational aspects of geoinformatics
  • Mike Worboys
  • NCGIA, University of Maine, USA

2
Overview
  • Much of the early technology for spatial data
    handling (e.g. spatial indices, object-oriented
    spatial data models) is now well understood.
  • A personal view of interesting current topics in
    computational geographic information science will
    be the subject of these lectures.
  • Topics will include
  • spatial reasoning
  • uncertainty
  • multi-contextuality levels of detail,
    integration, mode
  • adding time

3
1. Introduction and formal preliminaries
  • pre-requisites (sets, functions, relations)
  • kinds of relations
  • tolerance relation
  • equivalence relation
  • order relation
  • structures
  • poset
  • lattice
  • Boolean algebra
  • semilattice
  • closure system
  • topology
  •  

4
2. Spatial ontologies, cognition, integration
  • Representations of crisp and vague geographic
    entities.
  • Cognitive issues.
  • Spatial information integration.
  • Resources
  • Mark, D., Toward a theoretical framework for
    geographic entity types, COSIT, 1993.
  • Smith, B. and Varzi, A., Fiat and bona fide
    boundaries, Philosophy and Phenom. Research,
    2000.
  • Worboys, M. and Duckham, Commonsense notions of
    proximity and direction in environmental space,
    unpublished.
  • Worboys, M. and Duckham, M. Integrating
    spatio-thematic information. Second International
    Conference GIScience 2002, M. Egenhofer and D.
    Mark (eds.), Lecture Notes in Computer Science
    2478, Berlin SpringerVerlag.

5
3. Formal models of space and spatial reasoning
  • Spatial reasoning and computational
    representation, Egenhofer's intersection method
    and the RCC calculus. Issues in discretization.
    Key issues in spatial databases.
  •  
  • Resources
  • Cohn, A. and Hazarika, S., Qualitative spatial
    representation and reasoning An overview, Fund.
    Inf. 2001.
  • Egenhofer, M. and Franzosa, R., Point-set
    topological relations, IJGIS, 1991.
  • Egenhofer, M. and Herring, J., Categorizing
    binary topological relations between regions,
    lines and points in geographic databases, Tech.
    Rep. Department of Surveying Engineering,
    University of Maine, Orono, ME., 1991.
  • Guting, R. and Schneider, M., Realms A
    foundation for spatial data types in database
    systems, 3rd Int. Symp. on Large Spatial
    Databases, 14-35, Singapore, 1993.
  • Guting, R.H., An introduction to spatial database
    systems, VLDB Journ., 1994.
  • Randell, D., Cui, Z. and Cohn, A., A spatial
    logic based on regions and connection, 3rd Int.
    Conf. on KRR, 1992.
  • Smith, B., Topological foundations of cognitive
    science, workshop notes.

6
4. Imperfection and uncertainty in spatial
representation and reasoning
  • Typology of uncertainty, scale, granularity and
    roughness, vagueness, fuzzy sets, rough sets
    defined by tolerances and equivalences.
  •  
  • Resources
  • Cohn, A. and Gotts, N., A theory of spatial
    regions with indeterminate boundaries, 1994.
  • Goodchild, M. and Proctor, J., Scale in a digital
    geographic world, Geog. and Env. Modelling, 1997.
  • Jarvinen, J., Rough sets defined by tolerances,
    Rough Sets and Current Trends in Computing, 2000.
  • Pawlak, Z., Rough sets, IJ Comp Inf Sci, 1982.
  • Varzi, A., Vagueness in geography, Philosophy and
    Geography, 2002.
  • Zadeh, L. Fuzzy sets, Information and Control
    1965.

7
5. Models of the dynamic world
  • Ontology of movement and change, ST architectures
    (e.g. TRIPOD), ST-ontology, event and process
    models as front ends to STIS, representation and
    reasoning issues.
  •  
  • Resources
  • Allen, J., Maintaining knowledge about temporal
    intervals, Comm. ACM, 1983.
  • Allen, J., Towards a general theory of action and
    time, AI, 1984.
  • Griffiths, T. et al., Tripod A comprehensive
    system for the management of spatial and aspatial
    historical objects, ACM GIS Conf., 2001.
  • Guting et al., A foundation for representing and
    querying moving objects, ACM TODS, 2000.
  • Smith, B. SNAP/SPAN ontology. Unpublished notes.

8
Process issues
  • Classes
  • Mike Worboys formal presentations of material
    related to the course
  • Student presentation of key papers
  • Assessment
  • Students own presentation (including supporting
    material) (40)
  • Students notes of the presentation of others
    (30)
  • Class test (30)

9
Qualitative spatial reasoning (QSR)
  • Qualitative vs. quantitative (discrete vs.
    continuous).
  • Relevant discretizations.
  • Predictions, diagnoses and explanations of the
    behavior of spatial entities and systems.
  • The challenge of QSR is to provide calculi which
    allow a machine to represent and reason with
    spatial entities without resort to the
    traditional quantitative techniques prevalent in
    e.g. computer graphics or computer vision (Cohn
    and Hazarika)

10
Applications
  • GIS
  • Robotic and human navigation
  • Computer vision (e.g. object recognition through
    shape matching, scene description)
  • Spatial semantics of natural language
  • Common-sense reasoning about physical systems
  • Visual language syntax and semantics
  • ...

11
Ontology
  • Point-based and region-based ontologies.
  • Single and mixed dimensions
  • The nature of the embedding space (continuous vs.
    discrete)
  • Primitive entities, relationships and operations

12
Mereology and topology
  • Mereology and topology are key foundations of
    QSR.
  • Traditional mathematical topology may not be the
    appropriate formalization for topological
    relationships in QSR.
  • Alternative formalizations
  • Clarke, RCC
  • Egenhofer 4-intersection, 9-intersection
  • Boolean connection algebras
  • Key notions
  • part
  • connection
  • boundary

13
Richer structure
  • Orientation
  • Distance
  • Size
  • Shape (e.g. convexity)
  • Vagueness, uncertainty and granularity
  • Configuration

14
Change
  • Spatial and aspatial change
  • Motion
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