可迅速布置的機械手系統大學畢業論文外文文獻翻譯及原文畢業設計〔論文〕外文文獻翻譯文獻、資料中文題目：可迅速布置的機械手系統文獻、資料英文題目：ARapidlyDeployableManipulatorSystem文獻、資料來源：文獻、資料發表〔出版〕日期：院〔部〕：專業：班級：姓名：學號：指導老師：翻譯日期：2021.02.14畢業設計(論文)外文資料翻譯附件一：ARapidlyDeployableManipulatorSystemChristiaanJ.J.Paredis,H.BenjaminBrown,PradeepK.KhoslaAbstract:Arapidlydeployablemanipulatorsystemcombinestheflexibilityofreconfigurablemodularhardwarewithmodularprogrammingtools,allowingtheusertorapidlycreateamanipulatorwhichiscustom-tailoredforagiventask.Thisarticledescribestwomainaspectsofsuchasystem,namely,theReconfigurableModularManipulatorSystem(RMMS)hardwareandthecorrespondingcontrolsoftware.1IntroductionRobotmanipulatorscanbeeasilyreprogrammedtoperformdifferenttasks,yettherangeoftasksthatcanbeperformedbyamanipulatorislimitedbymechanicalstructure.Forexample,amanipulatorwell-suitedforprecisemovementacrossthetopofatablewouldprobablynobecapableofliftingheavyobjectsintheverticaldirection.Therefore,toperformagiventask,oneneedstochooseamanipulatorwithanappropriatemechanicalstructure.Weproposetheconceptofarapidlydeployablemanipulatorsystemtoaddresstheabovementionedshortcomingsoffixedconfigurationmanipulators.AsisillustratedinFigure1,arapidlydeployablemanipulatorsystemconsistsofsoftwareandhardwarethatallowtheusertorapidlybuildandprogramamanipulatorwhichiscustomtailoredforagiventask.ThecentralbuildingblockofarapidlydeployablesystemisaReconfigurableModularManipulatorSystem(RMMS).TheRMMSutilizesastockofinterchangeablelinkandjointmodulesofvarioussizesandperformancespecifications.OnesuchmoduleisshowninFigure2.Bycombiningthesegeneralpurposemodules,awiderangeofspecialpurposemanipulatorscanbeassembled.Recently,therehasbeenconsiderableinterestintheideaofmodularmanipulators[2,4,5,7,9,10,14],forresearchapplicationsaswellasforindustrialapplications.However,mostofthesesystemslackthepropertyofreconfigurability,whichiskeytotheconceptofrapidlydeployablesystems.TheRMMSisparticularlyeasytoreconfigurethankstoitsintegratedquick-couplingconnectorsdescribedinSection3.EffectiveuseoftheRMMSrequires,TaskBasedDesignsoftware.Thissoftwaretakesasinputdescriptionsofthetaskandoftheavailablemanipulatormodules;itgeneratesasoutputamodularassemblyconfigurationoptimallysuitedtoperformthegiventask.Severaldifferentapproacheshavebeenusedsuccessfullytosolvesimpli-fiedinstancesofthiscomplicatedproblem.Athirdimportantbuildingblockofarapidlydeployablemanipulatorsystemisaframeworkforthegenerationofcontrolsoftware.Toreducethecomplexityofsoftwaregenerationforreal-timesensor-basedcontrolsystems,asoftwareparadigmcalledsoftwareassemblyhasbeenproposedintheAdvancedManipulatorsLaboratoryatCMU.Thisparadigmcombinestheconceptofreusableandreconfigurablesoftwarecomponents,asissupportedbytheChimerareal-timeoperatingsystem[15],withagraphicaluserinterfaceandavisualprogramminglanguage,implementedinOnikaAlthoughthesoftwareassemblyparadigmprovidesthesoftwareinfrastructureforrapidlyprogrammingmanipulatorsystems,itdoesnotsolvetheprogrammingproblemitself.Explicitprogrammingofsensor-basedmanipulatorsystemsiscumbersomeduetotheextensiveamountofdetailwhichmustbespecifiedfortherobottoperformthetask.Thesoftwaresynthesisproblemforsensor-basedrobotscanbesimplifieddramatically,byprovidingrobustroboticskills,thatis,encapsulatedstrategiesforaccomplishingcommontasksintherobotstaskdomain[11].Suchroboticskillscanthenbeusedatthetasklevelplanningstagewithouthavingtoconsideranyofthelow-leveldetailsAsanexampleoftheuseofarapidlydeployablesystem,consideramanipulatorinanuclearenvironmentwhereitmustinspectmaterialandspaceforradioactivecontamination,orassembleandrepairequipment.Insuchanenvironment,widelyvariedkinematic(e.g.,workspace)anddynamic(e.g.,speed,payload)performanceisrequired,andtheserequirementsmaynotbeknownapriori.Insteadofpreparingalargesetofdifferentmanipulatorstoaccomplishthesetasks—anexpensivesolution—onecanusearapidlydeployablemanipulatorsystem.Considerthefollowingscenario:assoonasaspecifictaskisidentified,thetaskbaseddesignsoftwaredeterminesthetask.ThisoptimalconfigurationisthenassembledfromtheRMMSmodulesbyahumanor,inthefuture,possiblybyanothermanipulator.Theresultingmanipulatorisrapidlyprogrammedbyusingthesoftwareassemblyparadigmandourlibraryofroboticskills.Finally,themanipulatorisdeployedtoperformitstask.Althoughsuchascenarioisstillfuturistic,thedevelopmentofthereconfigurablemodularmanipulatorsystem,describedinthispaper,isamajorstepforwardtowardsourgoalofarapidlydeployablemanipulatorsystem.Ourapproachcouldformthebasisforthenextgenerationofautonomousmanipulators,inwhichthetraditionalnotionofsensor-basedautonomyisextendedtoconfiguration-basedautonomy.Indeed,althoughadeployedsystemcanhaveallthesensoryandplanninginformationitneeds,itmaystillnotbeabletoaccomplishitstaskbecausethetaskisbeyondthesystem’sphysicalcapabilities.Arapidlydeployablesystem,ontheotherhand,couldadaptitsphysicalcapabilitiesbasedontaskspecificationsand,withadvancedsensing,control,andplanningstrategies,accomplishthetaskautonomously.2Designofself-containedhardwaremodulesInmostindustrialmanipulators,thecontrollerisaseparateunithousingthesensorinterfaces,poweramplifiers,andcontrolprocessorsforallthejointsofthemanipulator.Alargenumberofwiresisnecessarytoconnectthiscontrolunitwiththesensors,actuatorsandbrakeslocatedineachofthejointsofthemanipulator.Thelargenumberofelectricalconnectionsandthenon-extensiblenatureofsuchasystemlayoutmakeitinfeasibleformodularmanipulators.Thesolutionweproposeistodistributethecontrolhardwaretoeachindividualmoduleofthemanipulator.Thesemodulesthenbecomeself-containedunitswhichincludesensors,anactuator,abrake,atransmission,asensorinterface,amotoramplifier,andacommunicationinterface,asisillustratedinFigure3.Asaresult,onlysixwiresarerequiredforpowerdistributionanddatacommunication.2.1MechanicaldesignThegoaloftheRMMSprojectistohaveawidevarietyofhardwaremodulesavailable.Sofar,wehavebuiltfourkindsofmodules:themanipulatorbase,alinkmodule,threepivotjointmodules(oneofwhichisshowninFigure2),andonerotatejointmodule.Thebasemoduleandthelinkmodulehavenodegrees-of-freedom;thejointmoduleshaveonedegree-of-freedomeach.ThemechanicaldesignofthejointmodulescompactlyfitsaDC-motor,afail-safebrake,atachometer,aharmonicdriveandaresolver.Thepivotandrotatejointmodulesusedifferentoutsidehousingstoprovidetheright-angleorin-lineconfigurationrespectively,butareidenticalinternally.Figure4showsincross-sectiontheinternalstructureofapivotjoint.EachjointmoduleincludesaDCtorquemotorand100:1harmonic-drivespeedreducer,andisratedatamaximumspeedof1.5rad/sandmaximumtorqueof270Nm.Eachmodulehasamassofapproximately10.7kg.Asingle,compact,X-typebearingconnectsthetwojointhalvesandprovidestheneededoverturningrigidity.Ahollowmotorshaftpassesthroughalltherotarycomponents,andprovidesachannelforpassageofcablingwithminimalflexing.2.2ElectronicdesignThecustom-designedon-boardelectronicsarealsodesignedaccordingtotheprincipleofmodularity.EachRMMSmodulecontainsamotherboardwhichprovidesthebasicfunctionalityandontowhichdaughtercardscanbestackedtoaddmodulespecificfunctionality.ThemotherboardconsistsofaSiemens80C166microcontroller,64KofROM,64KofRAM,anSMCCOM20020universallocalareanetworkcontrollerwithanRS-485driver,andanRS-232driver.ThefunctionofthemotherboardistoestablishcommunicationwiththehostinterfaceviaanRS-485busandtoperformthelowlevelcontrolofthemodule,asisexplainedinmoredetailinSection4.TheRS-232serialbusdriverallowsforsimplediagnosticsandsoftwareprototyping.Astackingconnectorpermitstheadditionofanindefinitenumberofdaughtercardswithvariousfunctions,suchassensorinterfaces,motorcontrollers,RAMexpansionetc.Inourcurrentimplementation,onlymoduleswithactuatorsincludeadaughtercard.Thiscardcontainsa16bitresolvertodigitalconverter,a12bitA/Dconvertertointerfacewiththetachometer,anda12bitD/Aconvertertocontrolthemotoramplifier;wehaveusedanofthe-shelfmotoramplifier(GalilMotionControlmodelSSA-8/80)todrivetheDC-motor.Formoduleswithmorethanonedegree-of-freedom,forinstanceawristmodule,morethanonesuchdaughtercardcanbestackedontothesamemotherboard.3Integratedquick-couplingconnectorsTomakeamodularmanipulatorbereconfigurable,itisnecessarythatthemodulescanbeeasilyconnectedwitheachother.Wehavedevelopedaquick-couplingmechanismwithwhichasecuremechanicalconnectionbetweenmodulescanbeachievedbysimplyturningaringhandtight;notoolsarerequired.AsshowninFigure5,keyedflangesprovidepreciseregistrationofthetwomodules.Turningofthelockingcollaronthemaleendproducestwodistinctmotions:firstthefingersofthelockingringrotate(withthecollar)about22.5degreesandcapturethefingersontheflanges;second,thecollarrotatesrelativetothelockingring,whileacammech