Abstract
Geographic information and GIS operations constitute the kernel of a geographic information system. However, most GIS fail to structure geographic information and operations with direct mappings to users' conceptual schemata and analytic needs. As a result, GIS data and operations tend to be system-dependent and switch from one system to another is not trivial. Since the conceptual schemata for structuring both declarative and procedure knowledge are system-independent, this paper suggests frameworks for structuring geographic information and operations from users' perspectives, hereby making GIS data and operations interoperable. Four related user conceptual models are identified. Location snapshots and mosaics represent a location-centered conceptualization, whereas entity and entity snapshot models suggest an entity-centered view of reality. Four levels of GIS functions include the task level, the semantic level, the syntactic level, and the interaction level. This paper concludes that the four conceptual models can provide direct mappings from users' concepts to data objects, whereas functions at the task and semantical levels appear to fit well into users' models for procedure knowledge. Therefore, structuring geographic information compatible to the four conceptual models and designing GIS functions at the task and semantical levels will advance to data models and GIS function independent of hardware and software.
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References
Albrecht, J., 1994. Universal elementary GIS tasks: beyond low-level commands, Proceedings Sixth International Symposium on Spatial Data Handling, pp. 209–222. Edinburgh.
Albrecht, J., 1995. Semantic net of universal elementary GIS functions. In ACSM/ASPRS Annual Convention and Exposition, Technical Papers, Vol. 4, (Auto-Carto 12), pp. 235–244.
Anderson, J. R., 1990, Cognitive Psychology and its Implications, 3rd ed., W. H. Freeman and Company, New York.
Buehler, K., 1994. OGIS Project Document 94-016. OGIS Reference Model. The Open GIS Foundation, Cambridge.
Burrough, P., 1992. Development of intelligent Geographical Information Systems. International Journal of Geographic Information Systems, VI (1): 1–11.
Calkins, H. and N. Obermeyer, 1991. Taxonomy for Surveying the Use and Value of Geographical Information. International Journal of Geographical Information Systems, 5(3):341–352.
Card, S., Moran, T. and A. Newell, 1983. The Psychology of Human-Computer Interaction. Lawrence Erlbaum Associates, Hillsdale.
Codd, E., 1970. A Relational Model of Data for Large Shared Data Banks. Communications of the ACM, 13(6).
Codd, E., 1981. Data Models in Database Management. ACM SIGMOD Record 11(2).
Densham, P. and M. Goodchild, 1992. Spatial Decision Support Systems: scientific report for the specialist meeting. NCGIA Technical Report 90-5, NCGIA, Santa Barbara.
Goodchild, M. F., 1992a, Geographical information science. International Journal of Geographical Information Systems, 6(1):31–45.
Goodchild, M. F., 1992b. Spatial Analysis Using GIS: a seminar workbook. NCGIA, Santa Barbara.
Huxhold, W., 1989, An Introduction to Urban Information Systems. Oxford University Press, New York.
Langran, G., 1992, Time in Geographic Information Systems. Taylor & Francis, New York.
Mark, David M., 1993, Toward a theoretical framework for geographic entity types. In Frank, A. U. and Campari, I.(Eds.): Spatial Information Theory: A Theoretical Basis for GIS, pp. 270–283, Springer-Verlag.
de Man, E., 1988. Establishing a Geographic Information System in Relation to Its use. International Journal of Geographical Information Systems, 2(3):257.
Medyckyj-Scott, D. and M. Blades, 1990. User's Cognitive Representations of Space: relevance to the design and use of GIS. Report 13, Midlands Regional Research Laboratory, University of Leicester.
OGF, 1993. The Open Geodata Interoperability Specification, Version 1.0, Preliminary Draft, November 15, 1993. Open GIS Foundation, Cambridge, MA.
Rhind, D. and N. Green, 1988. Design of Geographical Information System for a Heterogeneous Scientific Community. International Journal of Geographical Information Systems, 2(1):23–28.
Sinton, D., 1978, The inherent structure of information as a constraint to analysis: mapped thematic data as a case study. Harvard Papers on GIS, Volume 7, edited by G. Dutton, Addison-Wesley Publishing Company, Inc., Reading, MA.
SDTS, 1992. Spatial Data Transfer Standard. Federal information processing standards publication 173. Computer Systems Laboratory, National Institute of Standards and technology, Gaithersburg, MD.
Tobler, W., 1995, The resel-based GIS, International Journal of Geographical Information Systems, 9(1):95–100.
Unwin D., 1990. A syllabus for teaching Geographical Information Systems. International Journal of Geographical Information Systems, 4(4):461–462.
Yuan, M., 1994, Representation of Wildfire in Geographic Information, unpublished Ph.D. dissertation. State University of New York at Buffalo.
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Yuan, M., Albrecht, J. (1995). Structural analysis of geographic information and GIS operations from a user's perspective. In: Frank, A.U., Kuhn, W. (eds) Spatial Information Theory A Theoretical Basis for GIS. COSIT 1995. Lecture Notes in Computer Science, vol 988. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-60392-1_8
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DOI: https://doi.org/10.1007/3-540-60392-1_8
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