Writing Effective Use Cases
Building Product Models: Computer Environments Supporting Design and Construction
Building Product Models: Computer Environments Supporting Design and Construction
Use Case Modeling
Software Engineering (7th Edition)
Software Engineering (7th Edition)
Building information modelling - Experts' views on standardisation and industry deployment
Advanced Engineering Informatics
Modeling Our World: The ESRI Guide to Geodatabase Concepts
Modeling Our World: The ESRI Guide to Geodatabase Concepts
Advanced Engineering Informatics
Role-based access to facilities lifecycle information on RFID tags
Advanced Engineering Informatics
Localization of RFID-equipped assets during the operation phase of facilities
Advanced Engineering Informatics
Hi-index | 0.00 |
Some tasks in the construction industry and urban management field such as site selection and fire response management are usually managed by using a Geographical Information System (GIS), as the tasks in these processes require a high level and amount of integrated geospatial information. Recently, a key element of this integrated geospatial information to emerge is detailed geometrical and semantic information about buildings. In parallel, Building Information Models (BIMs) of today have the capacity for storing and representing such detailed geometrical and semantic information. In this context, the research aimed to investigate the applicability of BIMs in geospatial environment by focusing specifically on these two domains; site selection and fire response management. In the first phase of the research two use case scenarios were developed in order to understand the processes in these domains in a more detailed manner and to establish the scope of a possible software development for transferring information from BIMs into the geospatial environment. In the following phase of the research two data models were developed - a Schema-Level Model View and a geospatial data model. The Schema-Level Model View was used in simplifying the information acquired from the BIM, while the geospatial data model acted as the template for creating physical files and databases in the geospatial environment. Following this, three software components to transfer building information into the geospatial environment were designed, developed, and validated. The first component served for acquiring the building information from the BIM, while the latter two served for transforming the information into the geospatial environment. The overall research demonstrated that it is possible to transfer (high level of geometric and semantic) information acquired from BIMs into the geospatial environment. The results also demonstrated that BIMs provide a sufficient level and amount of (geometric and semantic) information (about the building) for the seamless automation of data management tasks in the site selection and fire response management processes.