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P2P cloud network services for IoT based disaster situations information

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Abstract

In order to cope with disaster situations properly, it is very important to identify the disaster scale and provide the accurate information of the site to the appropriate authorities including disaster site and Central Disaster Management Center, on-site command post, etc. and share the information provided. In particular, sharing information on disaster situations should control the disaster quickly to prevent the disaster situation from lasting and expanding. However, in the event of a large-scale disaster, delay is caused in the existing commercial network and therefore, the disaster situation cannot be communicated quickly and accurately. In order to determine the situation exactly in the event of a disaster, safety and connectivity of the network and flow of data are very important. Even if the stability of the network and connection of nodes are resolved in the network of each agency business operator, it is necessary to share the platform between networks for IoT/M2M communication for the smooth flow of data. Recently, the disaster safety net of combining existing disaster standard technology with Ubiquitous Technology and Smart IT such as Tetra of Europe, iDEN of the U.S., etc. has been built for disaster safety communications. In addition, systems useful for demand-centered, site-centered immediate disaster response by using Mobile, SNS, cloud computing, etc. are being built and designed to play an important role in the disaster information system especially through IoT, P2P cloud network, big data, etc. Therefore, in this paper, we proposed the P2P cloud network service for IoT based disaster situations information according to the paradigm of the changing times. The proposed service is to combine IoT/M2M network with P2P cloud service for rapid and smooth response in the event of a disaster and provide the results as social services such as SNS. To this end, the wide area wireless disaster information network system has been built in the local and each local network is connected to each other to provide disaster situations by using the server of the disaster area. At this time, each server was to be interconnected via P2P network and to be connected automatically by software-based network in P2P Cloud System. Also, the cognitive cycle was applied for selecting optimal wireless link and router of P2P Cloud-based Disaster Information Network and the danger situations of the disaster area were to be provided to the user by configuring disaster information component for providing services and building central disaster information platform managing it.

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Notes

  1. National Disaster Information Center, http://www.safekorea.go.kr/

  2. Daumkakao, http://www.daumkakao.com/en/

  3. Microsoft Cloud, http://www.microsoft.com/enterprise/microsoftcloud/platform/

  4. Jena, http://jena.apache.org/

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Acknowledgments

This research was supported by a grant (14CTAP-C078863-01) from Infrastructure and transportation technology promotion research Program funded by Ministry of Land, Infrastructure and Transport of Korean government.

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Authors and Affiliations

  1. School of Computer Information Engineering, Sangji University, 83, Sangjidae-gil, Wonju-si, Gangwon-do, 220-702, South Korea

    Kyungyong Chung

  2. Division of Computer Engineering, Dongseo University, 47, Jurye-ro, Sasang-gu, Busan, South Korea, 617-716

    Roy C. Park

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  1. Kyungyong Chung
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Correspondence to Roy C. Park.

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Chung, K., Park, R.C. P2P cloud network services for IoT based disaster situations information. Peer-to-Peer Netw. Appl. 9, 566–577 (2016). https://doi.org/10.1007/s12083-015-0386-3

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