Details Details PDF BIBTEX RIS Title The role of least image dimensions in generalization of object in spatial databases Journal title Geodesy and Cartography Yearbook 2010 Volume vol. 59 Numer No 2 Authors Chrobak, Tadeusz Keywords cartographic generalization ; databases – MRDB ; informatics ; statistics Divisions of PAS Nauki Techniczne Publisher Commitee on Geodesy PAS Date 2010 Type Artykuły / Articles Identifier DOI: 10.2478/v10277-012-0004-y ; ISSN 2080-6736 References Aslanikaschvili A. (1974), Cartography. Main Problems (in Polish). ; Bertin J. (1971), Graphics (in Polish), 1. ; Brassel K. (1988), A review and conceptual framework of automated map generalization, International Journal of Geographical Information Systems, 2, 3, 229, doi.org/10.1080/02693798808927898 ; Chrobak T. (1999), An Investigation of Elementary Triangle Usefulness for Computer Cartographic Generalization (in Polish). ; Chrobak T. (2007), Fundamentals of digital cartographic generalization (in Polish). ; Douglas D. (1973), Algorithms for the reduction of the number of points required to represent a digitized line or its caricature, The Canadian Cartographer, 10, 2, 112. ; Grünreich D. (1992), Research and Development in Computer-Assisted Generalization of Topographic Information at the Institute of Cartography, null, l, 36. ; Grünreich D. (1995), GIS and Generalization - Methodology and Practice, Great Britain, 47. ; Hake G. (1973), Kartographie und Kommunikation, Kartographische Nachrichten, 23, 4, 137. ; Kozioł K. (2006), Elimination of linear objects with the use of structural regions on the example of a road network, Annals of Geomatics, IV, 3, 109. ; Kulikowski J. (1986), Outline of graph theory. Applications of the technique (in Polish). ; Longley P. (2006), GIS and Science. ; (2007), Generalisation of geographic information: cartographic modeling and application. ; Molenaar M. (1996), The role of topologic and hierarchical spatial object models in database generalization, 13. ; Morrison J. (1974), A theoretical framework for cartographic generalization with emphasis on the process of symbolization, International Yearbook of Cartography, 14, 115. ; Nickerson B. (1986), Development of rule-based system for automatic map generalization, null, 537. ; Olszewski R. (2009), Cartographic modelling of terrain relief with the use of computational intelligence methods (in Polish). ; Ostrowski W. (2008), Semiotic Basis for Designing of Topographic Maps on the Example of Urban Areas (in Polish). ; Piątkowski F. (1969), Cartography, Editing of cartographic maps and their reproduction (in Polish). ; Preparata F. (1985), Computational Geometry. Introduction (in Polish), doi.org/10.1007/978-1-4612-1098-6 ; Ratajski L. (1989), Methodology of mapping the socio-economics (in Polish), 198. ; Richardson D.E., (1993): <i>Automatic spatial and thematic generalization using a context transformation model</i>, PhD Thesis, Wagering Agriculture University. Ottawa, Canada. ; Saalfeld A. (1999), Topologically Consistent Line Simplification with the Douglas - Peucker Algorithm, Cartography and Geographic Information Science, 26, 1, 7, doi.org/10.1559/152304099782424901 ; Saliszczew K. (1998), General Cartography (in Polish). ; Shea K. (1989), Cartographic generalization in a digital environment: When and How to generalize, null, 56. ; Strahler A. (1964), Handbook of applied hydrology, 39. ; Weibel R. (1995), Map generalization in the context of digital systems, Cartography and GIS, 22, 4, 56.