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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
2. THE USERS AND THE SYSTEM 
Disaster management is an application that involves a very 
wide group of users. Figure 1 shows a categorisation of the 
users according to the environments they are working in 
(related to their tasks in the emergency operations). Two 
general categories of users can be distinguished, i.e. teams 
working in wireless environments, on the field (indoor or 
outdoor) and users working in wired environments (indoor) in 
management centres and related institutions (Zlatanova and 
Holweg, 2004). The users in wired environments can be 
subdivided further into users working in VR environments 
(controlling, analysing and managing), Desktop environments 
(advising on particular situations and occasions) and accessing 
information through the Web (wide audience, press, etc.). In the 
centres for coordination, various pieces of information have to 
be assembled for decision-making. In the field, the workers 
need information about the current situation and prognosis for 
the immediate development in their area. Moreover the field 
workers can collect information to be returned to the central for 
analysis and redistribution. These generalised activities impose 
a variety of requirements such as consistent information in any 
environment, search, analysis and processing of information on 
the Internet and distributed databases, real-time data update, 
routing outdoor working teams, individual and intuitive 
visualisation on different devices to support decision-taking. 
      
  
Wireless Nelwork 
Internet&Intranet 
     
Figure 1: The users in a disaster management situation 
3. GEO-DBMS FOR DISASTER MANAGEMENT 
Most of the important data and information necessary for the 
support of such a system are spatially related; a geo-component 
is of special relevance. Amongst all the systems dealing with 
geo-information, DBMS are the fundamental componet. 
c 
3.1 State of the art in Geo-DBMS 
The integrated architecture of storing geometric data and 
relationships together with administrative data in DBMS’s is 
now getting mature. The importance of the integrated 
architecture was recognised by the industry and the OpenGIS 
consortium standardised the basic spatial types and functions 
(i.e. Simple Feature Specification, SFS) (OGC, 1999). ISO (ISO 
TC211, 2003) and OpenGIS agreed to harmonize their geo- 
information standards and specifications. Several commercial 
DBMSs are available with support for spatial data type: Ingres, 
Oracle, Informix or IBM DB2. In addition several heavily used 
non-commercial DBMS have  geo-information support: 
PostgreSQL (with roots more than two decades ago) and 
629 
MySQL (since the most recent version in 2004). Also more and 
more originally commercial CAD and GIS packages support the 
integrated architecture: ESRI, MapInfo, Intergraph Bentley or 
AutoDesk. Even one of the DBMSs (Oracle Spatial) has started 
supporting 2D topology in the most recent version (10g). 
Currently, the main attention is on 2D spatial data types, but 3D 
geometric objects can be maintained as well. Research on 3D 
has resulted in defining a 3D geometry data type (Stoter & van 
Oosterom, 2002, Arens et al., 2003). Recent experiments and 
benchmarking have clearly shown a significant progress in 
DBMS's performance (van Oosterom et al., 2002). Loading and 
querying spatial information is still more elaborate than 
semantic (attribute) data but the response time is compatible 
and can be tuned to meet requirements of disaster management 
where the response time is of critical importance (Zlatanova et 
al, 2003). 
3.2 Current and future developments 
Despite the progress shown within DBMSs developments, still 
a number of generic issues needs to be addressed in order to 
provide service to multi-risk management: 
e Extending the management functionality into the third 
dimension is a research question of critical importance for 
fighting crisis situations in urban areas. For example, true 
three-dimensional data (instead of 2D maps), supplied 
directly to a fire brigade working in a dense built-up area 
will increase the possibilities for orientation and reduce 
time, which significantly improves the effectiveness and 
safety of rescue teams. 
e Developing 3D models and frameworks for management 
of different topologies at database level and corresponding 
operations. This will allow extension of the spatial 
functionality to be able to perform 3D routing, 
generalisation, and adaptation of different types of data, 
and consistent field update of data. Some explicit examples 
of implementations related to mobile environments are 
map orientation, map generalisation, bounding box, route 
maps, map styles, and colouring. Some of this 
functionality can be provided as a generic set of operations 
at a database level. 
e Frameworks for describing multidimensional spatial 
relationships, structures for maintenance of 
multiresolution, multidimensional and historic geo-data 
need further research. Investigating and developing 
multidimensional and multimedia data models for efficient 
organisation of large urban models, utilising and 
elaborating different international specifications including 
ISO, OpenGIS etc. 
e Data update with newly collected data from the field can 
be very critical for both a) monitoring the disaster event 
and b) giving instructions to the involved people. From a 
database point of view, this process requires strict 
consistency rules for integration with existing models and 
immediate propagation of the information to all the users. 
In this respect, extended models for maintenance of 
historic information (to be used also for prognosis and 
future scenarios) are becoming especially desirable. 
e A major issue in disaster management is the presentation 
of the information. It has to be prepared in the best 
appropriate form. For example, navigation instructions to 
the closest exit can be presented as voice, text, simple 
graphics, animation or even 3D graphics. The time for 
delivering such formats differs significantly. The system 
has to be able to understand the context (type device,