Reynolds flocking in reality with fixed-wing robots: Communication range vs. maximum turning rate

Hauert,; Leven,; Varga,; Ruini, Fabio; Cangelosi, Angelo; Zufferey,; Floreano,

doi:10.1109/iros.2011.6048729

Cited by 53 publications

(70 citation statements)

References 4 publications

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“…New rules and algorithms related to the Boids model have been developed and analyzed in the last few decades. In the work of Hauert et al, the basic rules were expanded with a “migration” rule to be applied to fixed‐wing flying robots. Lee et al investigated the flocking control of second‐order systems based on the Boids model.…”

Section: Related Workmentioning

confidence: 99%

Distributed coordination with connectivity maintenance for nonholonomic robots

Huang

Wang

et al. 2018

Computer Animation & Virtual

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Multirobot systems have been studied extensively in the recent years. Maintaining connectivity has significant impacts on the stability and convergence of the multirobot systems. In this work, we design a three-layer framework for multirobot coordination. Furthermore, a novel distributed algorithm is proposed to achieve the navigation objective while satisfying connectivity maintenance and collision avoidance constraints. The algorithm is a hybrid of an rapidly exploring random tree-based planner and an extended distributed navigation function-based controller. The coordination framework and the distributed algorithm are demonstrated to be effective through a series of illustrative simulations. They outperform the current state-of-the-art method in terms of efficiency and applicability.

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Section: Related Workmentioning

confidence: 99%

Distributed coordination with connectivity maintenance for nonholonomic robots

Huang

Wang

et al. 2018

Computer Animation & Virtual

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“…This objective is reached using Reynolds rules to organize the robots distribution and movements. Hauert et al [30] apply flocking rules for the management of a drones swarm in order to keep an ad-hoc network during their flight and to coordinate their task. However, this application is based on the assumption of well-known search field, and then it is not applicable to unstructured environments, which is one of our requirements.…”

Section: Related Workmentioning

confidence: 99%

Swarm coordination of mini-UAVs for target search using imperfect sensors

Alfeo

Cimino

Francesco

et al. 2018

IDT

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Unmanned Aerial Vehicles (UAVs) have a great potential to support search tasks in unstructured environments. Small, lightweight, low speed and agile UAVs, such as multirotors platforms can incorporate many kinds of sensors that are suitable for detecting object of interests in cluttered outdoor areas. However, due to their limited endurance, moderate computing power, and imperfect sensing, mini-UAVs should be into groups using swarm coordination algorithms to perform tasks in a scalable, reliable and robust manner. In this paper a biologically-inspired mechanisms is adopted to coordinate drones performing target search with imperfect sensors. In essence, coordination can be achieved by combining stigmergic and flocking behaviors. Stigmergy occurs when a drone releases digital pheromone upon sensing of a potential target. Such pheromones can be aggregated and diffused between flocking drones, creating a spatiotemporal attractive potential field. Flocking occurs, as an emergent effect of alignment, separation and cohesion, where drones self organise with similar heading and dynamic arrangement as a group. The emergent coordination of drones relies on the alignment of stigmergy and flocking strategies. This paper reports on the design of the novel swarming algorithm, reviewing different strategies and measuring their performance on a number of synthetic and real-world scenarios

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“…The long term evolution of the swarm geometry will have te be evaluate together with the science requirements. With the frame of such a low-control swarm, there may be a need to implement a herding dog algorithm [48]. The homogeneous swarm concept makes all nodes interchangeable.…”

Section: System Architecturementioning

confidence: 99%

NOIRE study report: Towards a low frequency radio interferometer in space

Cecconi

Dekkali

Briand

et al. 2018

2018 IEEE Aerospace Conference

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Ground based low frequency radio interferometers have been developed in the last decade and are providing the scientific community with high quality observations. Conversely, current radioastronomy instruments in space have a poor angular resolution with single point observation systems. Improving the observation capabilities of the low frequency range (a few kHz to 100 MHz) requires to go to space and to set up a space based network of antenna that can be used as an interferometer.We present the outcome of the NOIRE (Nanosatellites pour un Observatoire Interférométrique Radio dans l'Espace / Nanosatellites for a Radio Interferometer Observatory in Space) study which assessed, with help of CNES' PASO 2 , the feasibility of a swarm of nanosatellites dedicated to a low frequency radio observatory. With such a platform, space system engineering and instrument development must be studied as a whole: each node is a sensor and all sensors must be used together to obtain a measurement. The study was conducted on the following topics: system principle and concept (swarm, node homogeneity); Space and time management (ranging, clock synchronization); Orbitography (Moon orbit, Lagrange point options); Telecommunication (between nodes and with ground) and networking; Measurements and processing; Propulsion; Power; Electromagnetic compatibility.No strong show-stopper was identified during the preliminary study, although the concept is not yet ready. Several further studies and milestones are identified. The NOIRE team will collaborate with international teams to try and build this next generation of space systems.978-1-5386-2014-4/18/$31.00 c 2018 IEEE 2 PASO -Architecture Platform for Orbital Systems -is CNES' crossdisciplinary team in charge of early mission and concept studies

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Reynolds flocking in reality with fixed-wing robots: Communication range vs. maximum turning rate

Cited by 53 publications

References 4 publications

Distributed coordination with connectivity maintenance for nonholonomic robots

Distributed coordination with connectivity maintenance for nonholonomic robots

Swarm coordination of mini-UAVs for target search using imperfect sensors

NOIRE study report: Towards a low frequency radio interferometer in space

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