I Cutting Edge Robotics 2010 Cutting Edge Robotics 2010 Edited by Vedran Kordic In-Tech intechweb.org Published by In-Teh In-Teh Olajnica 19/2, 32000 Vukovar, Croatia Abstracting and non-prot use of the material is permitted with credit to the source. Statements and opinions expressed in the chapters are these of the individual contributors and not necessarily those of the editors or publisher. No responsibility is accepted for the accuracy of information contained in the published articles. Publisher assumes no responsibility liability for any damage or injury to persons or property arising out of the use of any materials, instructions, methods or ideas contained inside. After this work has been published by the In-Teh, authors have the right to republish it, in whole or part, in any publication of which they are an author or editor, and the make other personal use of the work. © 2010 In-teh www.intechweb.org Additional copies can be obtained from: publication@intechweb.org First published September 2010 Printed in India Technical Editor: Zeljko Debeljuh Cover designed by Dino Smrekar Cutting Edge Robotics 2010, Edited by Vedran Kordic p. cm. ISBN 978-953-307-062-9 V Preface Robotics research, especially mobile robotics is a young eld. Its roots include many engineering and scientic disciplines from mechanical, electrical and electronics engineering to computer, cognitive and social sciences. Each of this parent elds is exciting in its own way and has its share in different books. This book is a result of inspirations and contributions from many researchers worldwide. It presents a collection of a wide range of research results in robotics scientic community. Various aspects of current research in robotics area are explored and discussed. We have tried to investigate the most important research areas of a really wide scope of robotic science. We hope you will enjoy reading the book as much as we have enjoyed bringing it together for you. The book presents efforts by a number of people. We would like to thank all the researchers and especially the chapter authors who entrusted us with their best work and it is their work that enabled us to collect the material for this book. Of course, great acknowledgments go to the people who invested their time to review all manuscripts and choose only the best ones. VII Contents Preface V 1. MotionControlofRobotsBasedonSensingsofHumanForcesandMovements 001 TaoLiu,ChunguangLi,KyokoShibataandYoshioInoue 2. ReactiveRobotControlwithHybridOperational TechniquesinaSeaportContainerTerminalConsideringtheReliability 019 SatoshiHoshinoandJunOta 3. Robustnonlinearcontrolofa7DOFmodel-scale helicopterunderwindgustsusingdisturbanceobservers 031 AdnanMartini,FrangoisLeonardandGabrielAbba 4. Pursuit-EvasionGamesinPresenceofObstaclesin UnknownEnvironments:towardsanoptimalpursuitstrategy 047 C.Giovannangeli,M.HeymannandE.Rivlin 5. MotionPlanningbyIntegrationofMultiplePoliciesforComplexAssemblyTasks 081 NatsukiYamanobe,HiromitsuFujii,TamioAraiandRyuichiUeda 6. RoboticStrategiestoAssistPilotsinLanding andTakeoffofHelicoptersonShipsandOffshore 099 AlexandreCampos,JacquelineQuintero,RoqueSaltarén,ManuelFerreandRafaelAracil 7. OptimalityPrinciplesandMotionPlanningofHuman-LikeReachingMovements 115 MikhailM.Svinin,IgorA.Goncharenko,ShigeyukiHosoeandYoshihitoOsada 8. AnExperimentalStudyofThree-Dimensional PassiveDynamicWalkingwithFlatFeetandAnkleSprings 131 TerumasaNarukawa,KazutoYokoyama,MasakiTakahashiandKazuoYoshida 9. ActiveKnee-releaseMechanismforPassive-dynamicWalkingMachines 145 KalinTrifonovandShujiHashimoto 10. SimpliedHumanHandModelsforManipulationTasks 155 SalvadorCobos,ManuelFerre,RafaelAracil,JavierOrtegoandM.ÁngelSanchéz-Urán VIII 11. AnImpactMotionGenerationSupportSoftware 175 TeppeiTsujita,AtsushiKonno,YukiNomura, ShunsukeKomizunai,YasarAyazandMasaruUchiyama 12. Peltier-BasedFreeze-ThawConnectorforWaterborneSelf-AssemblySystems 187 ShuheiMiyashita,FlurinCasanova,MaxLungarellaandRolfPfeifer 13. AdhesionForcesReductionbyOscillationandItsApplicationtoMicroManipulation 199 TetsuyouWatanabeandZhongWeiJiang 14. PassivitybasedcontrolofhydrauliclineararmsusingnaturalCasimirfunctions 215 SatoruSakai 15. TheFormationStabilityofaMulti-RoboticFormationControlSystem 227 Chih-FuChangandLi-chenFu 16. EstimationofUser’sRequestforAttentiveDeskworkSupportSystem 243 YusukeTamura,MasaoSugi,TamioAraiandJunOta 17. AdaptiveSwarmFormationControlforHybridGroundandAerialAssets 263 LauraBarnes,RichardGarcia,MaryAnneFieldsandKimonValavanis 18. IntelligentRobotSystemsbasedonPDA forHomeAutomationSystemsinUbiquitous 279 In-KyuSa,HoSeokAhn,YunSeokAhn,Seon-KyuSaandJinYoungChoi 19. OnboardMissionManagementfora VTOLUAVUsingSequenceandSupervisoryControl 301 FlorianAdolfandFranzAndert 20. EmotionRecognitionthroughPhysiological SignalsforHuman-MachineCommunication 317 ChoubeilaMAAOUIandAlainPRUSKI 21. RobotAssistedSmileRecovery 333 DushyanthaJayatilake,AnnaGruebler,andKenjiSuzuki 22. AugmentingSparseLaserScanswithVirtualScans toImprovethePerformanceofAlignmentAlgorithms 351 RolfLakaemper 23. Sensornetworkforstructuringpeopleandenvironmentalinformation 367 S.Nishio,N.Hagita,T.Miyashita,T.Kanda,N.Mitsunaga,M.ShiomiandT.Yamazaki 24. Minimallyinvasiveforcesensingfortendon-drivenrobots 379 AlbertoCavallo,GiuseppeDeMaria,CiroNataleandSalvatorePirozzi 25. TweezersTypeToolManipulationbya MultingeredHandUsingaHigh-speedVisualServoing 395 SatoruMizusawa,AkioNamiki,TakuSenooandMasatoshiIshikawa IX 26. Vision-BasedHapticFeedbackwithPhysically-BasedModelforTelemanipulation 411 JungsikKimandJungKim 27. ImageStabilizationforIn VivoMicroscopicImaging 429 SungonLee [...]... the 2005 IEEE 9th International Conference on Rehabilitation Robotics, Vol 28, 7/2005, pp 14 9 15 1 18 Cutting Edge Robotics 2 010 Reinkensmeyer, D.J.; Dewald, J.P.A & Rymer, W.Z (19 99) Guidance-based quantification of arm impairment following brain injury: a pilot study, IEEE Transactions on Rehabilitation Engineering, Vol 7, No 1, 3 /19 99, pp 1 11 , Reinkensmeyer, D.J.; Kahn, L.E.; Averbuch, M.; McKenna-Cole,... torque information was detected with the torque transducers The CLP 110 4 collected the speed and possition information though the incremental encoder interface, and worked out the control quantity  of the PWM siganl 10 Cutting Edge Robotics 2 010 with the motion control strategy, then though the PWM generation module in the slave DSP of the CLP 110 4 to offer PWM signal for the H-bridge driver, enabling the... closed-loop circuit of the master-slave control system is given in Fig 1, in which M 1 and M 2 represent the master motor and slave motor respectively Fig 1 Equivalent circuit of the master-slave control system Based on the dynamics mechanism, the motion equation is written as T1  TM 1  T0  TM 2  T2  T0 T  T  C i M2 T  M1 (1) where T1 and T2 are the mechanical torques in the master and slave motor... horizontal system considering efficient maintenance of the operating robots 20 Cutting Edge Robotics 2 010 Fig 1 Horizontal AGV transportation system in a seaport container terminal (top view) 2 Seaport Container Terminal 2 .1 Horizontal AGV transportation system In the horizontal AGV transportation system shown in Fig .1, quay container cranes (QCCs) at the quay side, automated transfer cranes (ATCs)... were 0.47 81 rad/s in speeds and 0. 011 2 rad in position Figure 7 (d) manifests that the supplementary energy was approximately coincident with Motion Control of Robots Based on Sensings of Human Forces and Movements 11 the resistance loss However, the former was slightly larger than the latter because the contact loss and excitation loss also occurred in the energy recycling circuit (refer to (10 )) We... corresponding results are given in Fig 8 Motion Control of Robots Based on Sensings of Human Forces and Movements 13 (a) A representative results of the input torque, the output torque and the difference between the input and output torques (b) Speed tracking curves of the motors 14 Cutting Edge Robotics 2 010 (c) Position tracking curves of the motors (d) The relation curve of resistance loss, compensated energy... Human Forces and Movements 5 1) Gearbox mechanism: In order to acquire a symmetric mechanism, two identical gearboxes are employed in the master and slave sites An equivalent circuit is shown in Fig 2 The gear transmission relationship can be expressed as  1  Nin ,  2  Nout  Tin  NT1 , Tout  NT2 (4) where N is the gear ratio of the two gearboxes; 1 ,  2 and T1 , T2 are still used to indicate... the speeds of the motors (a) A representative results of the input torque, the output torque and the difference between the input and output torques (b) Speed tracking curves of the motors 12 Cutting Edge Robotics 2 010 (c) Position tracking curves of the motors (d) The relation curve of resistance loss, compensated energy and electromagnetic power Fig 6 The results of the force sensing test 4.2 Active-assistance... the impaired limb without high-power motors, and being advantageous to reduce the weight as well as the volume of the system By combining (1) and (4), the relationship of the input electric power and output torque can be re-expressed as 6 Cutting Edge Robotics 2 010 Tin  Tout  2 NT0 (5) The difference between the input and output torques is magnified N times, thus a larger input torque is required... and slave motors can be written as  P1 _ M  CT iN1in  (12 )   P2 _ M  CT iN 2 out  which suggests that the master motor generates more electromagnetic power than the power required in the slave site when out equals to in If the two gear ratios are matched appropriately, the following relationship can be achieved P1 _ M  P2 _ M  2( p a  pb  p f ) (13 ) Thus the demand for energy supplement . I Cutting Edge Robotics 2 010 Cutting Edge Robotics 2 010 Edited by Vedran Kordic In-Tech intechweb.org Published by In-Teh In-Teh Olajnica 19 /2, 32000 Vukovar, Croatia Abstracting. dSPAC Am p lie Maste Slave H-brid g e Cutting Edge Robotics 2 010 10 with the motion control strategy, then though the PWM generation module in the slave DSP of the CLP 110 4 to offer PWM signal for the. September 2 010 Printed in India Technical Editor: Zeljko Debeljuh Cover designed by Dino Smrekar Cutting Edge Robotics 2 010 , Edited by Vedran Kordic p. cm. ISBN 978-953-307-062-9 V Preface Robotics