Control and navigation of UAVs formation : application to Quadrotors

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dc.contributor.author Allam, Ahmed
dc.contributor.other Tadjine, Mohamed, Directeur de thèse
dc.contributor.other Nemra, Abdelkrim, Directeur de thèse
dc.date.accessioned 2022-01-10T14:22:44Z
dc.date.available 2022-01-10T14:22:44Z
dc.date.issued 2021
dc.identifier.other T000364
dc.identifier.uri http://repository.enp.edu.dz/jspui/handle/123456789/10308
dc.description Thèse de Doctorat : Automatique : Alger, École Nationale Polytechnique : 2021 fr_FR
dc.description.abstract A cooperative Multi-Vehicles Systems/Multi-Agent Systems MVS/MASs can be characterized as a group of decisionmaking autonomous agents/vehicles operating together and seeking a common and collective objective (i.e., group behaviors) based on their sensed information and the shared inter-agents information. This thesis investigates the methods and techniques from a control point of view to maximize the overall gained performance of a robots-system when accomplishing cooperatively a given task in terms of stability, robustness, speed and tracking accuracy. The main objective is to design cooperative Time Varying Formation Tracking controllers for a group of networked vehicles, while tracking a formation reference trajectory. In the literature, classical MVS control approaches have been deeply investigated such as, behavioral based method, virtual structure approach and leader-Follower technique. However, these methods have been shown to be unified within the framework of Consensus techniques. Consensus technique (or protocol) refers to a control law designed for a group of agents (featured by a linear dynamics) to reach an agreement in some variable of interest (i.e., States). The consensus problems have been extended to a MVS formation control. In this thesis, we focus into designing distributed TVF tracking controllers for a networked MVS. The main contribution was into ensuring a distributed and a reduced network information exchange among the MVS individuals. In addition, practical assumptions have been relaxed such as the connectivity of the network. The MVS stability has been studied relying on Lyapunov theory. Numerical simulations have been provided to confirm the conjectures of the proposed developments with an application to multi-Quadrotors systems. fr_FR
dc.language.iso en fr_FR
dc.subject Cooperative control fr_FR
dc.subject Graph theory fr_FR
dc.subject Lyapunov theory fr_FR
dc.subject Multi-Agents systems fr_FR
dc.subject Formation tracking fr_FR
dc.subject Consensus techniques fr_FR
dc.subject Quadrotors fr_FR
dc.subject Mobile robots fr_FR
dc.title Control and navigation of UAVs formation : application to Quadrotors fr_FR
dc.type Thesis fr_FR


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