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200 10$aAuthorizing Porter Bros. & Biffle and others to institute suit. April 19 (calendar day, April 28), 1926. -- Ordered to be printed
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200 10$aIntroduction to mobile robot control /$fSpyros G. Tzafestas, School of Electrical and Computer Engineering, National Technical University of Athens, Athens, Greece
205   $aFirst edition.
210  1$aLondon :$cElsevier,$d2014.
215   $a1 online resource (xxiv, 691 pages) $cillustrations (some color)
225 1 $aElsevier insights
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225  0$aElsevier insights
300   $aDescription based upon print version of record.
311   $a0-12-417049-8 
311   $a1-299-96471-0 
320   $aIncludes bibliographical references.
327   $aFront Cover; Introduction to Mobile Robot Control; Copyright Page; Dedication; Contents; Preface; List of acknowledged authors and collaborators; Principal symbols and acronyms; Quotations about robotics; 1 Mobile Robots: General Concepts; 1.1 Introduction; 1.2 Definition and History of Robots; 1.2.1 What Is a Robot?; 1.2.2 Robot History; 1.2.2.1 Ancient and Preindustrial Period; 1.2.2.2 Industrial and Robosapien Period; 1.3 Ground Robot Locomotion; 1.3.1 Legged Locomotion; 1.3.2 Wheeled Locomotion; 1.3.2.1 Wheel Types; 1.3.2.2 Drive Types; 1.3.2.3 WMR Maneuverability; References
327   $a2 Mobile Robot Kinematics 2.1 Introduction; 2.2 Background Concepts; 2.2.1 Direct and Inverse Robot Kinematics; 2.2.2 Homogeneous Transformations; 2.2.3 Nonholonomic Constraints; 2.3 Nonholonomic Mobile Robots; 2.3.1 Unicycle; 2.3.2 Differential Drive WMR; 2.3.3 Tricycle; 2.3.4 Car-Like WMR; 2.3.5 Chain and Brockett-Integrator Models; 2.3.5.1 Unicycle WMR; 2.3.5.2 Rear-Wheel Driving Car; 2.3.6 Car-Pulling Trailer WMR; 2.4 Omnidirectional WMR Kinematic Modeling; 2.4.1 Universal Multiwheel Omnidirectional WMR; 2.4.2 Four-Wheel Omnidirectional WMR with Mecanum Wheels; References
327   $a3 Mobile Robot Dynamics 3.1 Introduction; 3.2 General Robot Dynamic Modeling; 3.2.1 Newton-Euler Dynamic Model; 3.2.2 Lagrange Dynamic Model; 3.2.3 Lagrange Model of a Multilink Robot; 3.2.4 Dynamic Modeling of Nonholonomic Robots; 3.3 Differential-Drive WMR; 3.3.1 Newton-Euler Dynamic Model; 3.3.2 Lagrange Dynamic Model; 3.3.3 Dynamics of WMR with Slip; 3.4 Car-Like WMR Dynamic Model; 3.5 Three-Wheel Omnidirectional Mobile Robot; 3.6 Four Mecanum-Wheel Omnidirectional Robot; References; 4 Mobile Robot Sensors; 4.1 Introduction; 4.2 Sensor Classification and Characteristics
327   $a4.2.1 Sensor Classification 4.2.2 Sensor Characteristics; 4.3 Position and Velocity Sensors; 4.3.1 Position Sensors; 4.3.2 Velocity Sensors; 4.4 Distance Sensors; 4.4.1 Sonar Sensors; 4.4.2 Laser Sensors; 4.4.3 Infrared Sensors; 4.5 Robot Vision; 4.5.1 General Issues; 4.5.2 Sensing; 4.5.2.1 Camera Calibration; 4.5.2.2 Image Acquisition; 4.5.2.3 Illumination; 4.5.2.4 Imaging Geometry; 4.5.3 Preprocessing; 4.5.4 Image Segmentation; 4.5.5 Image Description; 4.5.6 Image Recognition; 4.5.7 Image Interpretation; 4.5.8 Omnidirectional Vision; 4.6 Some Other Robotic Sensors; 4.6.1 Gyroscope
327   $a4.6.2 Compass 4.6.3 Force and Tactile Sensors; 4.6.3.1 Force Sensors; 4.6.3.2 Tactile Sensors; 4.7 Global Positioning System; 4.8 Appendix: Lens and Camera Optics; References; 5 Mobile Robot Control I: The Lyapunov-Based Method; 5.1 Introduction; 5.2 Background Concepts; 5.2.1 State-Space Model; 5.2.2 Lyapunov Stability; 5.2.3 State Feedback Control; 5.2.4 Second-Order Systems; 5.3 General Robot Controllers; 5.3.1 Proportional Plus Derivative Position Control; 5.3.2 Lyapunov Stability-Based Control Design; 5.3.3 Computed Torque Control; 5.3.4 Robot Control in Cartesian Space
327   $a5.3.4.1 Resolved Motion Rate Control
330   $aIntroduction to Mobile Robot Control provides a complete and concise study of modeling, control, and navigation methods for wheeled non-holonomic and omnidirectional mobile robots and manipulators. The book begins with a study of mobile robot drives and corresponding kinematic and dynamic models, and discusses the sensors used in mobile robotics. It then examines a variety of model-based, model-free, and vision-based controllers with unified proof of their stabilization and tracking performance, also addressing the problems of path, motion, and task planning, along with localization
410  0$aElsevier insights.
606   $aMobile robots$xAutomatic control
606   $aRobotics$xHuman factors
615  0$aMobile robots$xAutomatic control.
615  0$aRobotics$xHuman factors.
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250   $a3. éd. revue et corrigée
260   $aParis :$bO.C.D.L.,$c1969-
300   $a3 volumi :$bill. ;$c21 cm
500   $aTraduzione di Pierre Roy
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