Jürgen Scherer scite author profile

This paper proposes and evaluates a modular architecture of an autonomous unmanned aerial vehicle (UAV) system for search and rescue missions. Multiple multicopters are coordinated using a distributed control system. The system is implemented in the Robot Operating System (ROS) and is capable of providing a real-time video stream from a UAV to one or more base stations using a wireless communications infrastructure. The system supports a heterogeneous set of UAVs and camera sensors. If necessary, an operator can interfere and reduce the autonomy. The system has been tested in an outdoor mission serving as a proof of concept. Some insights from these tests are described in the paper.

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Persistent multi-UAV surveillance with energy and communication constraints

Scherer

Rinner

2016

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We discuss surveillance with multiple unmanned aerial vehicles (UAV) that minimize idleness (the time between consecutive visits of sensing locations) and constrain latency (the time between capturing data at a sensing location and its arrival at the base station). This is important in persistent surveillance scenarios where sensing locations should not only be visited periodically, but the captured data also should reach the base station in due time even if the area is larger than the communication range. Our approach employs the concept of minimum-latency paths (MLP) to guarantee that the data reaches the base station within a predefined latency bound. To reach the bound, multiple UAVs cooperatively transport the data in a store-and-forward fashion. Additionally, MLPs specify a lower bound for any latency minimization problem where multiple mobile agents transport data in a store-and-forward fashion. We introduce three variations of a heuristic employing MLPs and compare their performance in a simulation study. The results show that extensions of the simplest of our approaches, where data is transported after each visit of a sensing location, show improved performance and the tradeoff between latency and idleness.

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Experimental performance analysis of two-hop aerial 802.11 networks

Yanmaz

Hayat

Scherer

et al. 2014

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UAV trajectory optimization for Minimum Time Search with communication constraints and collision avoidance

Pérez-Carabaza

Scherer

Rinner

et al. 2019

Engineering Applications of Artificial Intelligence

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Short and full horizon motion planning for persistent multi-UAV surveillance with energy and communication constraints

Scherer

Rinner

2017

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Jürgen Scherer

An Autonomous Multi-UAV System for Search and Rescue

Persistent multi-UAV surveillance with energy and communication constraints

Experimental performance analysis of two-hop aerial 802.11 networks

UAV trajectory optimization for Minimum Time Search with communication constraints and collision avoidance

Short and full horizon motion planning for persistent multi-UAV surveillance with energy and communication constraints

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