Abstract
In the aftermath of a large-scale emergency, Unmanned Aerial Vehicles (UAVs) can play a key role as mobile communication systems supporting rescue operations on the ground. At the same time, the deployment of autonomous UAV swarms still poses severe challenges in terms of distributed mobility, swarm connectivity and mesh networking. To this purpose, we propose ELAPSE (aErial LocAl Positioning System for Emergency), a novel, distributed framework for aerial mesh deployment that supports discovery and multi-hop connectivity among rescue personnel and emergency requesters. ELAPSE integrates components of swarm mobility, positioning and Quality-of-Service (QoS) support, while targeting UAV devices at different levels of hardware complexity. Three contributions are provided in this study. First, we present a novel, bio-inspired swarm mobility algorithm which natively addresses QoS-based aerial mesh connectivity, coverage of the ground nodes and UAV collision avoidance through the abstraction of virtual springs. Second, we investigates its implementation when geo-location capabilities are not available: to this aim, we propose local-based and cooperative-based techniques through which each UAV can estimate the position of its neighbours, and hence correctly adjust its direction and speed. Third, we analyze the feasibility of the ELAPSE framework through a twofold evaluation: i.e. a large-scale OMNeT++ simulation showing the effectiveness of the distributed mesh formation and localization techniques, and a small-case ground robotic testbed demonstrating the impact of QoS mechanisms on the system operations.
Highlights
Unmanned aerial Vehicles (UAVs) are expected to play a key role in generation mobile systems, thanks to the their integrated and advanced capabilities of perception, autonomous mobility and wireless communications
We extend the Quality of Service (QoS)-aware UAV swarm mobility model in [28] for disaster environments: the distributed algorithm aims to maximize the number of connected Mobile Ground Nodes (MGNs), while guaranteeing the quality of the AtA and Air to Ground (AtG) links
We investigate the implementation of the proposed swarm mobility algorithm on scenarios where geolocation capabilities are not available: to this aim, two distributed neighbour localization schemes are presented, one based on local sensor data processing (e.g. Inertial Measurement Unit (IMU) and Wi-Fi RSSI values) and the other on cooperative mechanisms
Summary
Unmanned aerial Vehicles (UAVs) are expected to play a key role in generation mobile systems, thanks to the their integrated and advanced capabilities of perception, autonomous mobility and wireless communications. B. CONTRIBUTIONS In this paper, we consider a generic emergency scenario composed of isolated, mobile ground nodes (MGNs) belonging to two different categories -rescue personnel (RP) and help requesters (HR)-, and we investigate the deployment of distributed aerial mesh networks aimed to provide wireless coverage of the target area and multi-hop connectivity between RP and HR nodes. CONTRIBUTIONS In this paper, we consider a generic emergency scenario composed of isolated, mobile ground nodes (MGNs) belonging to two different categories -rescue personnel (RP) and help requesters (HR)-, and we investigate the deployment of distributed aerial mesh networks aimed to provide wireless coverage of the target area and multi-hop connectivity between RP and HR nodes To this aim, we propose ELAPSE (aErial LocAl Positioning System for Emergency), a distributed UAV swarm architecture that addresses mobilityrelated (e.g. aerial connectivity), task-related (e.g. ground coverage) and networking-related functionalities.
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