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  • Gebundenes Buch

This book reveals innovative control architectures that can lead to fully autonomous vehicle navigation in complex environments. Accessible to researchers and graduate students, it presents novel techniques and concepts that address different complex mobile robot tasks. Covering mono- and multi-robot navigation, the book describes components related to task modeling, planning, and control. Extensive simulations and experiments illustrate the methodology, and software technologies and algorithms are discussed for the experiments. MATLAB® and Simulink® code is available on the author's website.

Produktbeschreibung
This book reveals innovative control architectures that can lead to fully autonomous vehicle navigation in complex environments. Accessible to researchers and graduate students, it presents novel techniques and concepts that address different complex mobile robot tasks. Covering mono- and multi-robot navigation, the book describes components related to task modeling, planning, and control. Extensive simulations and experiments illustrate the methodology, and software technologies and algorithms are discussed for the experiments. MATLAB® and Simulink® code is available on the author's website.
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Autorenporträt
Lounis Adouane is an associate professor at the Institut Pascal - Polytech Clermont-Ferrand in France. He received an MS in 2001 from IRCCyN-ECN Nantes, where he worked on the control of legged mobile robotics. In 2005, he obtained a PhD in automatic control from FEMTO-ST laboratory-UFC Besançon. During his PhD studies, he deeply investigated the field of multi-robot systems, especially those related to bottom-up and hybrid control architectures. Dr. Adouane's current research topics are related to both autonomous navigation of mobile robots in complex environments and cooperative control architectures for multi-robot systems. More specifically, his main research include planning and control, hybrid multi-controller architectures, obstacle avoidance, cooperative robotics, artificial intelligence (such as Markov decision process, multi-agent systems, and fuzzy logic), and multi-robot/agent simulation. He is the author/coauthor of more than 60 refereed international papers on these topics.