Abstract
Disasters are uncertain occasions that can impose a drastic impact on human life and building infrastructures. Information and Communication Technology (ICT) plays a vital role in coping with such situations by enabling and integrating multiple technological resources to develop Disaster Management Systems (DMSs). In this context, a majority of the existing DMSs use networking architectures based upon the Internet Protocol (IP) focusing on location-dependent communications. However, IP-based communications face the limitations of inefficient bandwidth utilization, high processing, data security, and excessive memory intake. To address these issues, Named Data Networking (NDN) has emerged as a promising communication paradigm, which is based on the Information-Centric Networking (ICN) architecture. An NDN is among the self-organizing communication networks that reduces the complexity of networking systems in addition to provide content security. Given this, many NDN-based DMSs have been proposed. The problem with the existing NDN-based DMS is that they use a PULL-based mechanism that ultimately results in higher delay and more energy consumption. In order to cater for time-critical scenarios, emergence-driven network engineering communication and computation models are required. In this paper, a novel DMS is proposed, i.e., Named Data Networking Disaster Management (NDN-DM), where a producer forwards a fire alert message to neighbouring consumers. This makes the nodes converge according to the disaster situation in a more efficient and secure way. Furthermore, we consider a fire scenario in a university campus and mobile nodes in the campus collaborate with each other to manage the fire situation. The proposed framework has been mathematically modeled and formally proved using timed automata-based transition systems and a real-time model checker, respectively. Additionally, the evaluation of the proposed NDM-DM has been performed using NS2. The results prove that the proposed scheme has reduced the end-to-end delay up from 2 % to 10 % and minimized up to 20 % energy consumption, as energy improved from 3 % to 20 % compared with a state-of-the-art NDN-based DMS.
Highlights
Communications in the current Internet Protocol (IP) architecture focus on end-to-end connectivity
The simulation scenario is limited to an smart campuses (SCs) because we have compared this scheme with Named Data Networking (NDN)-DISCA [13], and NDN-DISCA has only been applied to an SC scenario
We will extend this work to different scenarios, e.g., smart cities and smart homes, in order to evaluate the scheme in different scenarios
Summary
Communications in the current Internet Protocol (IP) architecture focus on end-to-end connectivity. Internet of Things (IoT) devices use IP addresses to interact with each other, i.e., the client sends requests toward a specific server and the request is satisfied by the server. An IoT network consists of many such wireless devices that interact with the physical environment for collecting surrounding information and providing several services with the help of Internet [6,7]. The motivation toward IoT is the utilization of smart and intelligent devices for enabling and automating various services [8,9]. By using IoT, smart applications can be built, such as smart homes, smart cities, smart buildings, and smart campuses (SCs) [10,11]. Many companies are building IoT-based DMSs, such as the ZIZMOS and RIO projects funded by SBIR and IBM, respectively [13]
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