Title :
Geometry-Based Virtual Simulation for Fire Escape in Emergency Environment
Author :
Xiang Chen ; Yang Li
Author_Institution :
Hangzhou Inst. of Service Eng., Hangzhou Normal Univ., Hangzhou, China
Abstract :
The paper research the choosing of the optimal escape routes in fire emergency simulation. Aiming at the lack of fire emergency behavior description and its path pre-processing mechanism without dynamic adapting, this paper presented a novel algorithm based on geometry method in order to make the simulation according with the facts. We abstracted complex scenes as the graph model, and established an adaptive dynamic path query table to create the dynamically generated map, and proposed a model of population density to restrict the escape expectation velocity, which reflects the population movement of social group behavior in emergency situations. Experimental results show that the algorithm can not only access the dynamic optimal escape route, but also realistically describe the crowd social escape behavior under fire emergency situations.
Keywords :
computational geometry; directed graphs; disasters; emergency management; fires; query processing; adaptive dynamic path query table; complex scene abstraction; crowd social group escape behavior; dynamic optimal escape route; dynamically generated map creation; emergency environment; escape expectation velocity; fire emergency behavior description; fire emergency simulation; fire emergency situations; geometry-based virtual simulation; graph model; optimal fire escape routes; path preprocessing mechanism; population density model; population movement; Distributed computing; crowd density; dynamic-path; escape routes; geometric space;
Conference_Titel :
Networking and Distributed Computing (ICNDC), 2013 Fourth International Conference on
Conference_Location :
Los Angeles, CA
Print_ISBN :
978-1-4799-3045-6
DOI :
10.1109/ICNDC.2013.36
