This page intentionally left blank BIOMIMETIC ROBOTICS Thisbookiswrittenasaninitialcourseinrobotics.Itisidealforthe study of unmanned aerial or underwater vehicles, a topic on which few books exist. It presents the fundamentals of robotics, from an aerospace perspective, by considering only the field of robot mech- anisms. For an aerospace engineer, three-dimensional and parallel mechanisms – flight simulation, unmanned aerial vehicles, and space robotics – take on an added significance. Biomimetic robot mecha- nismsarefundamentaltomanipulatorsandwalking,mobile,andflying robots.Asadistinguishingfeature,thisbookgivesaunifiedandinte- grated treatment of biomimetic robot mechanisms. It is ideal prepa- ration for the next robotics module: practical robot-control design. Although the book focuses on principles, computational procedures are also given due importance. Students are encouraged to use com- putationaltoolstosolvetheexamplesintheexercises.Theauthorhas also included some additional topics beyond his course coverage for theenthusiasticreadertoexplore. Ranjan Vepa has been with Queen Mary and Westfield College in the Department of Engineering since 1984, after receiving his Ph.D. from Stanford University. Dr. Vepa’s research covers, in addition to biomimetic robotics, aspects of the design, analysis, simulation, and implementation of avionics and avionics-related systems, including nonlinear aerospace vehicle kinematics, dynamics, vibration, control, and filtering. He has published numerous journal and conference papers and has contributed to a textbook titled Application of Arti- ficial Intelligence in Process Control. He is active in learning-based designeducationandtheutilizationofmoderntechnologyinengineer- ing education. Dr. Vepa is a Chartered Engineer, a Member of the Royal Aeronautical Society (MRAeS) London, and a Fellow of the HigherEducationAcademy. Biomimetic Robotics mechanisms and control Ranjan Vepa QueenMary,UniversityofLondon CAMBRIDGE UNIVERSITY PRESS Cambridge, New York, Melbourne, Madrid, Cape Town, Singapore, São Paulo Cambridge University Press The Edinburgh Building, Cambridge CB2 8RU, UK Published in the United States of America by Cambridge University Press, New York www.cambridge.org Information on this title: www.cambridge.org/9780521895941 © Ranjan Vepa 2009 This publication is in copyright. Subject to statutory exception and to the provision of relevant collective licensing agreements, no reproduction of any part may take place without the written permission of Cambridge University Press. First published in print format 2009 ISBN-13 978-0-511-50691-8 eBook (EBL) ISBN-13 978-0-521-89594-1 hardback Cambridge University Press has no responsibility for the persistence or accuracy of urls for external or third-party internet websites referred to in this publication, and does not guarantee that any content on such websites is, or will remain, accurate or appropriate. Tomyfather,NarasimhaRow,andmother,Annapurna Contents Preface pagexiii Acronyms xv 1. TheRobot . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.1 Robotics:AnIntroduction 1 1.2 Robot-ManipulatorFundamentalsandComponents 5 1.3 FromKinematicPairstotheKinematicsofMechanisms 12 1.4 NovelMechanisms 13 1.4.1 Rack-and-PinionMechanism 14 1.4.2 Pawl-and-RatchetMechanism 14 1.4.3 Pantograph 15 1.4.4 Quick-ReturnMechanisms 15 1.4.5 AckermannSteeringGear 16 1.4.6 SunandPlanetEpicyclicGearTrain 17 1.4.7 UniversalJoints 17 1.5 SpatialMechanismsandManipulators 18 1.6 MeetProfessordaVincitheSurgeon,PUMA,andSCARA 20 1.7 BacktotheFuture 23 exercises 24 2. BiomimeticMechanisms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 2.1 Introduction 25 2.2 PrinciplesofLeggedLocomotion 27 2.2.1 InchwormLocomotion 29 2.2.2 WalkingMachines 30 2.2.3 AutonomousFootstepPlanning 31 2.3 ImitatingAnimals 31 2.3.1 PrinciplesofBirdFlight 33 2.3.2 MechanismsBasedonBirdFlight 34 2.3.3 SwimmingLikeaFish 37 vii viii Contents 2.4 BiomimeticSensorsandActuators 39 2.4.1 ActionPotentials 43 2.4.2 MeasurementandControlofCellularActionPotentials 46 2.4.3 BionicLimbs:InterfacingArtificialLimbstoLivingCells 47 2.4.4 ArtificialMuscles:FlexibleMuscularMotors 51 2.4.5 ProstheticControlofArtificialMuscles 53 2.5 ApplicationsinComputer-AidedSurgeryandManufacture 55 2.5.1 SteadyHands:ActiveTremorCompensation 56 2.5.2 DesignofScalableRoboticSurgicalDevices 58 2.5.3 RoboticNeedlePlacementandTwo-HandSuturing 60 exercises 61 3. HomogeneousTransformationsandScrewMotions . . . . . . . . . . . . 62 3.1 GeneralRigidMotionsinTwoDimensions 62 3.1.1 InstantaneousCentersofRotation 64 3.2 RigidBodyMotionsinThreeDimensions:DefinitionofPose 64 3.2.1 HomogeneousCoordinates:TransformationsofPosition andOrientation 65 3.3 GeneralMotionsofRigidFramesinThreeDimensions:Frames withPose 66 3.3.1 TheDenavit–HartenbergDecomposition 66 3.3.2 InstantaneousAxisofScrewMotion 67 3.3.3. AScrewfromaTwist 69 exercises 70 4. DirectKinematicsofSerialRobotManipulators . . . . . . . . . . . . . . 74 4.1 DefinitionofDirectorForwardKinematics 74 4.2 TheDenavit–HartenbergConvention 74 4.3 PlanarAnthropomorphicManipulators 76 4.4 PlanarNonanthropomorphicManipulators 78 4.5 KinematicsofWrists 80 4.6 DirectKinematicsofTwoIndustrialManipulators 81 exercises 86 5. ManipulatorswithMultiplePosturesandCompositions. . . . . . . . . . 89 5.1 InverseKinematicsofRobotManipulators 89 5.1.1 TheNatureofInverseKinematics:Postures 91 5.1.2 SomePracticalExamples 95 5.2 ParallelManipulators:Compositions 99 5.2.1 ParallelSpatialManipulators:TheStewartPlatform 101 5.3 WorkspaceofaManipulator 105 exercises 107