A cooperative multi-robot team for the surveillance of shipwreck survivors at sea

Mendonca, Ricardo; Marques, Mario Monteiro; Marques, Francisco; Lourenço, André; Pinto, Eduardo; Santana, Pedro; Coito, Fernando; Lobo, Victor; Barata, José

doi:10.1109/oceans.2016.7761074

Cited by 39 publications

(39 citation statements)

References 18 publications

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“…While a lot of research was undertaken regarding the autonomous landing of UAVs in general, few studies have been directed at marine environments where the challenges are more complex or circumstances are more dramatic compared to land or indoor environments. Recently, quadrotor UAVs have been landed with reasonable accuracy on swimming objects and under outdoor conditions (Mendona et al, 2016). The abilities to perform complex maneuvers and to operate as large collectives of units, especially for efficient situational awareness (Erdelj et al, 2017), are going to continue to increase rapidly over the next years.…”

Section: Introductionmentioning

confidence: 99%

Distributed Uav-Swarm-Based Real-Time Geomatic Data Collection Under Dynamically Changing Resolution Requirements

Almeida¹,

Hildmann

Solmaz³

2017

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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Unmanned Aerial Vehicles (UAVs) have been used for reconnaissance and surveillance missions as far back as the Vietnam War, but with the recent rapid increase in autonomy, precision and performance capabilities -and due to the massive reduction in cost and size -UAVs have become pervasive products, available and affordable for the general public. The use cases for UAVs are in the areas of disaster recovery, environmental mapping & protection and increasingly also as extended eyes and ears of civil security forces such as fire-fighters and emergency response units. In this paper we present a swarm algorithm that enables a fleet of autonomous UAVs to collectively perform sensing tasks related to environmental and rescue operations and to dynamically adapt to e.g. changing resolution requirements. We discuss the hardware used to build our own drones and the settings under which we validate the proposed approach.

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Section: Introductionmentioning

confidence: 99%

Distributed Uav-Swarm-Based Real-Time Geomatic Data Collection Under Dynamically Changing Resolution Requirements

Almeida¹,

Hildmann

Solmaz³

2017

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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“…USVs can also be used as carriers or support of other types of unmanned vehicles (e.g. UAVs [71][72][73][74], AUVs [75]) or act as communication relays between over-the-air/satellite communication and underwater vehicles/structures [8], or as data-mules [24].…”

Section: Unmanned Surface Vehiclesmentioning

confidence: 99%

Survey on Communication and Networks for Autonomous Marine Systems

Zolich

Palma²,

Kansanen

et al. 2018

J Intell Robot Syst

102

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The rapid development of autonomous systems and Information and Communications Technologies (ICT) create new opportunities for maritime activities. Existing autonomous systems are becoming more powerful and utilise the capabilities of several types of devices such as Autonomous Underwater Vehicles (AUVs), Unmanned Surface Vehicles (USVs)sometimes referred as Autonomous Surface Vehicles (ASVs) -, Unmanned Aerial Vehicles (UAVs), moored and drifting systems and, recently emerging, autonomous vessels. Their importance in providing new services in maritime environments is undeniable and the opportunity for coordinated and interconnected operations is clear. However, continuous wide integration of various technologies in maritime environments still faces many challenges. Operations may take place in remote locations, so that dependence on third-party infrastructures such as satellite communication or terrestrial communication systems must be expected. The reliability, performance, availability, and cost of such systems are important issues that need to be tackled. This work reviews the major advancements on state-of-the-art autonomous maritime vehicles and systems, which are used in several different scenarios, from scientific research to transportation. Moreover, the paper highlights how available technologies can be composed in order to efficiently and effectively operate in maritime environments. Highlights of the trade-off between autonomy and communication requirements are provided and followed by an overview of promising communication and networking technologies that could encourage the integration of autonomous systems in maritime scenarios.

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“…A group of robots can be used for accomplishing many tasks such as moving large awkward objects, terrain model acquisition, planetary exploration, surveillance applications [8,9,10,11]. Formation of mobile robots control methods can be partitioned into three class approaches: virtual structure approach [12,13], behavioral approach [14,15] and the leaderfollower approach [16,17,18].…”

Section: Introductionmentioning

confidence: 99%

Performance comparison of consensus protocol and l-&phi approach for formation control of multiple nonholonomic wheeled mobile robots

Alouache

2017

J. Mechatron. Electr. Power Veh. Technol.

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This paper investigates formation control of multiple nonholonomic differential drive wheeled mobile robots (WMRs). Assume the communication between the mobile robots is possible where the leader mobile robot can share its state values to the follower mobile robots using the leader-follower notion. Two approaches are discussed for controlling a formation of nonholonomic WMRs. The first approach is consensus tracking based on graph theory concept, where the linear and angular velocity input of each follower are formulated using first order consensus protocol, such that the heading angle and velocity of the followers are synchronized to the corresponding values of the leader mobile robot. The second is l- approach (distance angle) that is developed based on Lyapunov analysis, where the linear and angular velocity inputs of each follower mobile robot are adjusted such that the followers keep a desired separation distance and deviation angle with respect to the leader robot, and the overall system is asymptotically stable.The aim of this paper is to compare the performances of the presented methods for controlling a formation of wheeled mobile robots with matlab simulations.

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A cooperative multi-robot team for the surveillance of shipwreck survivors at sea

Cited by 39 publications

References 18 publications

Distributed Uav-Swarm-Based Real-Time Geomatic Data Collection Under Dynamically Changing Resolution Requirements

Distributed Uav-Swarm-Based Real-Time Geomatic Data Collection Under Dynamically Changing Resolution Requirements

Survey on Communication and Networks for Autonomous Marine Systems

Performance comparison of consensus protocol and l-&phi approach for formation control of multiple nonholonomic wheeled mobile robots

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