CI P A 2003 XIX th International Symposium, 30 September - 04 October, 2003, Antalya, Turkey 
If possible, it is recommended that DEM of the area generated 
by LIDAR technology. In case of the lack of the LIDAR, 
instead of automatic image matching, points selected by the 
operator will avoid discrepancies due to relief and plant cover of 
the area. 
5. ARCHEOLOGICAL INFORMATION SYSTEM 
Geographical Information System (GIS) can simply be defined 
as a digital environment, which is capable of data storage, 
analysis, interpretation and presentation and comprises of 
software, hardware and data components. Since the software 
and hardware could be supplied at reasonable costs including 
the training, main difficulty at establishing a GIS comes out to 
be the data acquisition, which is the most time consuming and 
costly component of the system. 
Data component of a GIS includes the aerial and/or satellite 
images, digitized maps, digitally compiled photogrammetric 
maps, digital or digitized ground photos and drawings, field 
survey data collected by GPS and all means of digital data. 
Since government agencies and other organizations make use of 
computer-based mapping and analytical tools in a variety of 
management, planning, and research activities, in order to keep 
in pace with the widely used GIS, photogrammetric mapping 
today has become a data acquisition for GIS (Jacobsen 2002a). 
Preservation of cultural sites has traditionally been oriented 
toward the protection and restoration of built structures, but 
there is now a trend toward the protection of larger sites and a 
monument's surrounds. This trend calls for new tools and 
methods for site documentation and management, such as GIS 
(Hardy 1997). The benefits of GIS has been discussed in vast 
number of publications so it will not be again emphasized but 
there is no doubt that it is a powerful tool for cultural resource 
managing, procurement planning and documentation of the 
heritage within the archeological site. 
There are numerous GIS that have been generated for different 
historical and archeological sites. The one developed for 
Mycenae (Ionnidis et al 2003) has been overviewed and it has 
been resolved that a similar geo-based archeological 
information system could be applied for Zeugma. Since all 
documentation is computerized, in order to complete the data 
component of the system all it has be done is obtaining the 
products that are described in section 4.3. 
6. CONCLUSION 
The benefits of a GIS include more accurate and accessible 
documentation of sites, and improved monitoring, maintenance 
and planning of sites. By developing an archeological GIS that 
displays the locations and boundaries of the remains of the 
Zeugma, both state and local authorities will be capable of 
monitoring the archeological work that are being conducted in 
the areas of their proposed projects. At the same time, by adding 
the project locations to the GIS system, meaningful predictive 
models of archeological site location can be developed using 
existing information pertaining to the environmental and 
cultural characteristics associated with the presence or absence 
of sites in previously surveyed areas. 
The Southeastern Anatolia Project assigns specific importance 
to the protection and promotion of the cultural heritage of the 
region, which has its roots in the early civilizations of the world. 
The concept of sustainable development also covers "cultural 
continuity" whereby this heritage is transferred to future 
generations. 
Until now, extraordinary efforts have been exposed in order to 
rescue the remains of Zeugma and, from now on, intensive labor 
shall be carried on with the help of both domestic and 
international volunteer organizations. However, it should be 
noted that it is a matter of considerable time and money to 
undertake an archeological project on such large area. 
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