《現(xiàn)代傳感器》課件:Lecture9_第1頁(yè)
《現(xiàn)代傳感器》課件:Lecture9_第2頁(yè)
《現(xiàn)代傳感器》課件:Lecture9_第3頁(yè)
《現(xiàn)代傳感器》課件:Lecture9_第4頁(yè)
《現(xiàn)代傳感器》課件:Lecture9_第5頁(yè)
已閱讀5頁(yè),還剩50頁(yè)未讀, 繼續(xù)免費(fèi)閱讀

下載本文檔

版權(quán)說(shuō)明:本文檔由用戶(hù)提供并上傳,收益歸屬內(nèi)容提供方,若內(nèi)容存在侵權(quán),請(qǐng)進(jìn)行舉報(bào)或認(rèn)領(lǐng)

文檔簡(jiǎn)介

ModernSensors

Lecture9X.WuAReviewofLecture8AnoverviewofModernIRsensorsQuantum,e.g.MCTThermalMicrobolometerPyroAnanalysisofthermalIRsensorSensitivityMicrobolometerUncooledIRsensorarrayBasicIntent

Thislecturewilldiscussthebasicprinciplesbehinduseofelectromagnetisminsensing.Sincemanyestablishedsensorsrelyonelectromagnetism,thislecturewillcoverabroadsetofdesignsandreviewseveralproducts.

ElectromagnetismandInductanceAreviewofthepropertiesofaninductorasusedinelectroniccircuits.apassivecircuitelementwhichresistschangesincurrent.Theequationwhichgovernsitsbehavioris:assume(asforallofthedifferentialequationsinthiscourse)thatthecurrentandvoltagearebothoscillatingquantities:

Effective

R=-iLAnalogy:inductorv.s.resistorinductancemeasuringcircuits,

exactlyliketheresistancemeasuringcircuitsthemostcommonapproachtoinductancemeasurementisabridge.Howbigisatypicalinductance?acoilwitha1cmdiameter,a1cmlength,with1000loopsofwire:mH

Effectiveresistance@1kHz=60Whatisreallypreferredforaninductor?Highinductance:Thisachievedinawaythatisverymuchlikewhatisdoneincapacitors:materialandareaInaninductor,wecanfillthecoilwithamaterialwhichhasahighermagneticpermittivity.ironhasarelativepermittivityof~300,

permalloy(nickel/iron80/20)~5000TheconceptofinductanceIfwehaveasimplecoil,andtrytosuddenlycauseacurrenttoflowthroughit,theinitialcurrentflowcausesamagneticfieldtobegintoforminthecoil.Sincethismagneticfieldisincreasing,thereisachangeinthefluxthroughthecoil,andanopposingvoltageappears.Eventually,thecurrentrisestoitslimitingvalue,themagneticfieldisstable,andtheopposingvoltagediesaway.MagneticmotiondetectorThemagneticfieldisconfinedtotheregionbetweenthepolefaces,andisessentiallyzeroelsewhere.Themagneticfluxthroughtheloopsissimplytheareaoftheloopthatiswithinthemagneticfieldtimesthevalueofthefield.Avoltageisinducedintheloopwheneveritmoveslaterally.Motionsensor,notapositionsensorMagneticMotionDetectoranditsTransferfunctionsGeophonesThisapproachisthebasisofmanyso-called`movingcoil'detectors,inwhichavoltageisgeneratedwheneveranexternalsignalcausesacoiltomoverelativetoapermanentmagnet.Agoodexampleofacommercialproduct:theGeophone,asmadebyGeoSpaceCorpInthisdevice,asetofcoilsmeasureadifferentialvoltagewheneveraspring-supportedmagnetmovesgenerallyconstructedwithafairlylowfrequencyresonance-about1Hmonlyusedfordetectionofseismicsignalsorotherlow-frequencygroundvibrations,orintheoilexplorationbusinesswithburiedexplosivechargestomapundergroundresourcedeposits.GeophoneSeismometerThesensitivityofageophoneisafunctionoffrequency

canbealteredbyfeedingbacktheconventionaloutput.Thiswillnotimprovetheresolution,butwillamplifylowfrequencysignals.However,theresolutioncanbeimprovedbymeasuringproofmassposition.ExistingGeophones/SeismometersWhatisaconventionalgeophone?Howdoesitwork?(Mechanicalsensitivity)Howdoesitwork?(Electricalsensitivity)TotalSensitivityResolutionConventionalGeophoneResolutionHowtoimprovebothsensitivityandresolution?Changealow-costgeophoneintoacapacitiveoneCapacitanceElectricalSystemControlSystemDesignControllerDesignConceptsPredictedandMeasuredPerformanceAComparisonofPerformanceExperimentalSetupatStanfordProximitySensorApairofcoilsarewiredinabridgecircuitandbiasedwithanacsignal.Ifaconductingobjectispositionedneartheendofthedevice,itisclosertothesensecoilthanthereferencecoil.Thepresenceofaconductorcauseanadditionalopposingvoltageinthecoil,andtheeffectistoincreasetheinductanceofthecoils.Sincethesensecoilisclosertothesheet,itsinductanceisincreasedmore.SensingcoilReferencecoilProximitySensing:bridgecircuitTheeffectofthesensecoilchangingmorethanthereferencecoilTheamplitudeofthisdifferenceisproportionaltotheinductancedifference-whichisrelatedtothedistancetothemetalsheetinaverycomplicatedway.Theactualrelationbetweendistanceandinductancechangeistoocomplicatedtoderiveingeneral,sinceitreliesonthegeometryofthesituation,sothisapproachisnotgenerallyusedforaccuratepositionsensing.CommercialInductiveProximitySensorsApplicationsAutomationRobotics……CommercialinductivesensorInthissystem,theamountofmagneticfieldfromonecoilthatisdirectedtowardspartofasecondcoilisdependentonthepositionofaferromagneticelement.Thetwohalvesofthepick-upcoil(wiredtoVout)arewoundinoppositedirections.Iftheferromagnetwerenotpresent,thefluxineachhalfofthepick-upcoilwouldbeequalandopposite,andVoutwouldbezero.Whentheferromagnetispositionedinthemiddle,thereisalsoacompletecancellationoftheflux.However,whenevertheferromagnetisdisplaced,thefluxbalanceischanged,andtheneteffectisthattherewillbeavoltageacrossthepickupcoilwhoseamplitudeisproportionaltothedisplacementoftheferromagnetfromitscenterposition.CaseStudy:GiantmagnetoresistanceGMRdiscoveredin1988independentlybyBaibich

etal.inParisandBinasch

etal.in

Jülich.Itisthephenomenonwheretheresistanceofcertainmaterialsdropsdramaticallyasamagneticfieldisapplied.ItisdescribedasGiantsinceitisamuchlargereffectthanhadeverbeenpreviouslyseeninmetals.Ithasgeneratedinterestfrombothphysicists&deviceengineers,asthereisbothnewphysicstobeinvestigatedandhugetechnologicalapplicationsinmagneticrecordingandsensors.

Outline IntroductionScienceofGMRAnisotropicmagnetoresistanceGiantmagnetoresistanceDiscoveryofGMRFert’sandGrünberg’soriginalpapersFurtherresearchbyIBMApplicationofGMRGMR-basedspinvalvesinharddrivesImpactofGMRonthestoragemediaindustryGMR–whyisituseful?DiscoveryandapplicationoftheGMRphenomenonisresponsiblefortheubiquitousavailabilityofeconomical,highdensityinformationstorageinoursociety.Compact160GBMp3playersand1TBharddrives,nowwidelyavailable,owetheirexistencetoGMRandsubsequentrelatedadvances.ScienceofGMR

AnisotropicMagnetoresistanceAnisotropicMagnetoresistance–Reportedin1857byBritishphysicistLordKelvin.Whenacurrentispassedthroughamagneticconductor,resistancechangesbasedontherelativeanglebetweenthecurrentandtheconductor’smagnetization.Resistanceincreaseswhencurrentisperpendiculartomagnetizationanddecreaseswhencurrentisparalleltomagnetization.Cause:electronspin-orbitcouplingUsedasthebasisofharddrivereadingbeforeGMRwasdiscovered.ScienceofGMR

GiantmagnetoresistanceSystem:athinlayerofnonmagneticmaterialsandwichedbetweentwolayersofmagneticmaterial.Right:aFe-Cr-FetrilayerusedinGrünberg’soriginalexperiment.[3]ScienceofGMR:MottModelTheelectricalconductivityinmetalscanbedescribedintermsoftwolargelyindependentconductingchannels,correspondingtotheup-spinanddown-spinelectrons,andelectricalconductionoccursinparallelforthetwochannels.Inferromagneticmetalsthescatteringratesoftheup-spinanddown-spinelectronsaredifferent.(Wewillassumethatthescatteringisstrongforelectronswithspinantiparalleltothemagnetizationdirectionandweakforelectronswithspinparalleltothemagnetizationdirection.)ScienceofGMR

GiantmagnetoresistanceParallelmagnetizationUp-spinelectronsexperiencesmallresistance,down-spinelectronsexperiencelargeresistance.Totalresistanceis

ScienceofGMR

GiantmagnetoresistanceAntiparallelmagnetizationBothelectronspinsexperiencesmallresistanceinonelayerandlargeresistanceintheother.Totalresistanceis

ScienceofGMR

GiantMagnetoresistanceDifferenceinresistanceisgivenby:DiscoveryofGMR

FertandGrünbergDiscoveredbyindependentlybyProfessorAlbertFertofUniversitéParis-SudinFranceandProfessorPeterGrünbergofForschungszentruminJülich,Germany.BothgroupssubmittedpaperstoPhysicalReviewinthesummerof1988.DiscoveryofGMR

Fert60-bilayeredFe-Crstructureat4.2KNearly50%dropinresistanceobserved!![5]DiscoveryofGMR

GrünbergFe-Cr-Fetrilayeratroomtemperature1.5%dropinresistancereported[3]DiscoveryofGMR

IBMStuartParkinofIBMattemptedtoreproducetheeffectusingthesputteringtechniqueFertandGrünbergusedmolecularbeamepitaxy,amoreprecisebutslowerandmoreexpensivemethod.Parkin’sgroupsucceeded,observingGMRinthefirstmultilayersample’sproduced.Parkin’sgroupbeganexperimentingwithvarioussamplecompositionsandlayerthicknessestobetterunderstandGMRandhowtointegrateitintomagneticstorage.GMRinpractice

SpinValve[7].[8]GMR’seffectonharddriveindustryFirstGMRharddrivedeployed:16.8GB,IBM,1997Currentlargestharddrive:1TBbyHitachi,20074TB,2012[11][12]CaseStudy:GiantmagnetoresistanceGMRhasbeenthesubjectofahugeinternationalresearcheffortduetothenumeroustechnologicalapplications.Thelargestisinthedatastorageindustry:IBMTheeffectismostusuallyseeninmagneticmultilayeredstructures,wheretwomagneticlayersarecloselyseparatedbyathinspacerlayerafewnmthick.CaseStudy:GMRItisanalogoustoapolarisationexperiment,wherealignedpolarisersallowlighttopassthrough,butcrossedpolarisersdonot.Thefirstmagneticlayerallowselectronsinonlyonespinstatetopassthrougheasily-ifthesecondmagneticlayerisalignedthenthatspinchannelcaneasilypassthroughthestructure,andtheresistanceislow.Ifthesecondmagneticlayerismisalignedthenneitherspinchannelcangetthroughthestructureeasilyandtheelectricalresistanceishigh.GMR:SpinValveAspinvalveisingeneralasampleconsistingessentiallyofaGMR

trilayer:Onelayerisverymagneticallysoft-meaningitisverysensitivetosmallfields.Theotherismademagnetically'hard'byvariousschemes-meaningitisinsensitivetofieldsofmoderatesize.Asthesoft'free'layermovesaboutduetoappliedfields,theresistanceofthewholestructurewillvary.Thecentralpartofthesampleconsistsoftwomagneticlayers(inourcaseusuallypermalloywithathincoveringofCo),separatedbyaCuspcerlayer.Onemagneticlayerispinnedorexchangebiasedbyanantiferromagneticmaterial-usingFeMnandIrMn,

CaseStudy:GiantMagnetoresistanceBrain-computerinterfaceBytheendofthisyear,SanFrancisco–basedEmotiv'ssensor-ladenEPOCheadsetenablegamerstousetheirownbrainactivitytointeractwiththevirtualworldswheretheyplay.headset's14strategicallyplacedheadsensorsareattheendsofwhatlooklikestretched,plasticfingersthatdetectpatternsproducedbythebrain'selectricalactivity.detectsbrainactivitynoninvasivelyusingelectroencephalography(EEG),ameasureofbrainwaves,viaexternalsensorsalongthescalpthatpickuptheelectricalbustleinvariouspartsofthefurrowedsurfaceofthebrain'scortex,aregionthathandleshigherorderthoughts.Theseneuralsignalsarethennarroweddownandinterpretedin30possiblewaysasreal-timeintentions,emotionsorfacialexpressionsthatarereflectedinvirtualworldcharactersandactions

EEGandMEGElectroencephalography(EEG)isthemeasurementofelectrical

activityproducedbythebrain

asrecordedfromelectrodes

placedonthescalp.MEGSensorArrayFielddistributionby510coilsatdistinctlocations.Coilsconfiguredinto306MEGchannels.Thecoilconfigurationoptimallycombinesthefocals

溫馨提示

  • 1. 本站所有資源如無(wú)特殊說(shuō)明,都需要本地電腦安裝OFFICE2007和PDF閱讀器。圖紙軟件為CAD,CAXA,PROE,UG,SolidWorks等.壓縮文件請(qǐng)下載最新的WinRAR軟件解壓。
  • 2. 本站的文檔不包含任何第三方提供的附件圖紙等,如果需要附件,請(qǐng)聯(lián)系上傳者。文件的所有權(quán)益歸上傳用戶(hù)所有。
  • 3. 本站RAR壓縮包中若帶圖紙,網(wǎng)頁(yè)內(nèi)容里面會(huì)有圖紙預(yù)覽,若沒(méi)有圖紙預(yù)覽就沒(méi)有圖紙。
  • 4. 未經(jīng)權(quán)益所有人同意不得將文件中的內(nèi)容挪作商業(yè)或盈利用途。
  • 5. 人人文庫(kù)網(wǎng)僅提供信息存儲(chǔ)空間,僅對(duì)用戶(hù)上傳內(nèi)容的表現(xiàn)方式做保護(hù)處理,對(duì)用戶(hù)上傳分享的文檔內(nèi)容本身不做任何修改或編輯,并不能對(duì)任何下載內(nèi)容負(fù)責(zé)。
  • 6. 下載文件中如有侵權(quán)或不適當(dāng)內(nèi)容,請(qǐng)與我們聯(lián)系,我們立即糾正。
  • 7. 本站不保證下載資源的準(zhǔn)確性、安全性和完整性, 同時(shí)也不承擔(dān)用戶(hù)因使用這些下載資源對(duì)自己和他人造成任何形式的傷害或損失。

評(píng)論

0/150

提交評(píng)論