International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004 
technology from outside the geospatial community, from 
disciplines such as CAD, Synthetic Environments and 
Virtual Reality. In such a hybrid approach, the geospatial 
data would provide a framework, with hooks for the more 
complex 3D models. Providing this in a seamless manner is 
a serious research topic. 
There is a useful stage beyond 2.5D and short of full 3D 
topology, which supports structuring of 3D geometries 
without losing z-value information. Topological structuring 
takes place in the projection to the (x,y) plane, with snapping 
in the z-direction controlled by a z-tolerance (see Fig. 6). 
[=e : 
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Nodes Emm : EE 
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Z snap tolerance = 1m 
Figure 6. Snapping in the z-direction. 
Implementations of this have existed for some time (Hayles, 
2001) and an implementation using Oracle as the database 
will appear in 2004. This level of topology support lacks an 
agreed name although 2.75D has been suggested and would 
appear appropriate. 
6. SUMMARY AND CONCLUSIONS 
In the discussion that followed the presentation of an earlier 
paper on Integration at the Vienna ISPRS conference 
(Woodsford, 1996), 1 ventured the polemical suggestion that 
in time photogrammetric system functionality would become 
so standardised that the major discriminating factor would be 
openness of their API and the ease with which they could be 
integrated with database technology. This was, and remains, 
an over-statement of the case. The continuing richness of 
new imagery sources, and the new functionality needed to 
exploit them, continues to provide major discriminating 
factors. This paper has deliberately restricted its focus to the 
role of photogrammetry in creating and sustaining vector 
databases. It has not attempted to cover other important tasks 
such as the creation and refinement of DEM data. A wider 
view, with an extensive set of references is to found in 
(Heipke, 2004). 
The benefits to be realised by closer integration and better 
data management are of increasing value and are not 
restricted to the vector domain. The paper has demonstrated 
that, with the increasing adoption of richer and more capable 
data models, these benefits are becoming crucial. Interfaces 
to support integration are becoming more open and more 
robust. Vendors, whilst seeking to maintain competitive edge 
in their distinctive capabilities, are becoming more inclined 
to work with providers of complementary capabilities. 
Openness and support for integration have become key 
discriminating factors. 
The convergence of disciplines represented by the ISPRS is 
thus being realised in the practical integration of technologies 
764 
available, against a wider background of convergence with 
the mainstream of the Information Technology and 
Communications (ICT) industries. The geomatics manager 
of the future will be an information manager, with skills in 
selecting the best sources and processes for enhancing the 
organisation's information holdings, and delivering products 
and services from them. The geomatics practitioners, whilst 
retaining particular skills in photogrammetry, cartography or 
image processing will be equally at home in the GIS domain, 
and the systems they use will be increasingly those needed to 
support them as geospatial information ‘all-rounders’. 
References from Journals: 
Heipke, C, 2004. Some Requirements for Geographic 
Information Systems: A Photogrammetric Point of View. 
Photogrammetric Engineering & Remote Sensing Vol. 70, 
No. 2, February 2004, pp. 185-195. 
References from Other Literature: 
Edwards, D., Simpson J, and Woodsford P., 2000. 
Integration of photogrammetric and spatial information 
systems, [International Archives of Photogrammetry and 
Remote Sensing, 33(B2): 603—609. 
EuroSDR. 2004. Workshop on Impacts of improving the 
positional accuracy of GI databases. Dublin, May 2004. To 
be available via Official Publications at www.eurosdr.org. 
Garland, P. 2004. Maximize Geodata Use: Move from 
Image Management to Workflow Management, March/April 
2004 issue of Earth Imaging Journal ^ available at 
www.eijournal.com. 
Murray, K. 2003. Official Publication no. 45: - OEEPE 
Workshop on Next Generation Spatial Databases — 2003. 
Available via Official Publications at www.eurosdr.org. 
Ohlhof, T, Gülch, E., Müller, H., Wiedemann, C., and Torre 
M. 2004. Semi-Automatic extraction of line and area 
features from aerial and satellite images. ISPRS Congress 
2004 Istanbul, Commission III, WG III/4. 
Woodsford, P., 1996. Spatial database update — a key to 
effective automation, International Archives of 
Photogrammetry and Remote Sensing, 31(4):956—961. 
References from Websites: 
ESRI, 2003.  ArcGIS'M: Working With Geodatabase 
Topology at: 
http://www esri.com/library/whitepapers/pdfs/geodatabase- 
topology.pdf. «accessed 27 April 2004). 
Hayles, M. 2001. Integration of photogrammetry and 3D 
geo-spatial databases. OEEPE/ISPRS Workshop “From 2D 
to 3D — Establishment and Maintenance of National Core 
Geospatial Databases", Hannover, Germany, October 2001. 
http://www. ipt.uni-hannover.de/isprs-wg2- 
A/oeepe01 pdfs/hayles.pdf. (accessed 27 April 2004). 
ICA, 2003. Commission on Incremental Updating and 
Versioning. Proceedings available via: 
http:Zgeo.haifa.ac.il/-icaupdt. (accessed 27 April 2004). 
Intergraph et al (2004). Oracle Interoperability Initiative at: 
http://imgs.intergraph.com/interop/oracle.asp. (accessed 27 
April 2004). 
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