|
Marinus Maris, & Gregor Pavlin. (2006). Distributed perception networks for crisis management. In M. T. B. Van de Walle (Ed.), Proceedings of ISCRAM 2006 – 3rd International Conference on Information Systems for Crisis Response and Management (pp. 376–381). Newark, NJ: Royal Flemish Academy of Belgium.
Abstract: Situation assessment in crisis management applications can be supported by automated information fusion systems, such as Distributed Perception Networks. DPNs are self-organizing fusion systems that can infer hidden events through interpretation of huge amounts of heterogeneous and noisy observations. DPNs are a logical layer on top of existing communication, sensing, processing and data storage infrastructure. They can reliably and efficiently process information of various quality obtained from humans and sensors through the existing communication systems, such as mobile phone networks or internet. In addition, modularity of DPNs supports efficient design and maintenance of very complex fusion systems. In this paper, a fully functional prototype of a DPN system is presented that fuses information from gas sensors and human observations. The task of the system is to compute probability values for the hypothesis that a particular gas is present in the environment. It is discussed how such a system could be used for crisis management.
|
|
|
Elina Valtonen, Ronja Addams-Moring, Teemupekka Virtanen, Antti Järvinen, & Mikael Moring. (2004). Emergency announcements to mobile user devices in geographically defined areas. In B. C. B. Van de Walle (Ed.), Proceedings of ISCRAM 2004 – 1st International Workshop on Information Systems for Crisis Response and Management (pp. 151–156). Brussels: Royal Flemish Academy of Belgium.
Abstract: When emergency announcements (EA) to a population in a crisis area are needed, avoiding single points of failure in the EA sending and forwarding systems is essential. We present a new concept, an extension to existing EA sending systems, which is based on real-time location information about mobile devices. Such a solution would increase the EA sending systems' robustness through redundancy and technology diversity. At the same time, these mobile emergency announcement (MEA) sending systems would increase the percentage of the threatened population that can be reached fast. The proposition is based on a set of requirements for EA sending systems, the most important of which turned out to be ensuring the authenticity and integrity of the EA information content. We found our preliminary results too optimistic: current GSM networks should not be used for sending EAs, as it is quite possible to forge SMS text messages, even to multiple GSM phones in a specific target area. The next generations of mobile phone networks (3G/UMTS and 4G) seem more promising, due to their packet-oriented architectures, as each data packet can be stamped with verifiable information about the source of the data. However, the development of communications networks with features compatible with MEA sending will demand that both authorities and independent experts take an active, early role in networks design right beside the commercial organisations. © Proceedings ISCRAM 2004.
|
|