人体热释电红外传感器PIR原理

1、1.人体热释电红外传感器 PIR 原理详解在电子防盗、 人体探测器领域中， 被动式热释电红外探测器的应用非常广泛， 因其价格低廉、 技术性能稳定而受到广大用户和专业人士的欢迎。被动式热释电红外探头的工作原理及特性：人体都有恒定的体温，一般在 37 度，所以会发生特定波长 10 以 m 左右的红外线， 被动式红外探头就是靠探测人体发射的10 以 m&右的红外线而进行工作的。人体发射的 10pm 左右的红外线通过菲涅尔滤光片增强后聚集到红外感应源上。 红外感应源通常采用热释电元件， 这种元件在接收到人体红外辐射温度发生变化时就会失去电荷平衡， 向外释放电荷， 后续电路经检测处理后就能产生报

2、警信号。(1)这种探头是以探测人体辐射为目标的。所以热释电元件对波长为 10pm 左右的红外辐射必须非常敏感。(2)为了仅仅对红外辐射敏感，在它的辐射照面通常覆盖有特殊的菲涅尔滤光片，使环境的干扰受到明显的控制作用。(3)被动红外探头，具传感器包含两个互相串联或并联的热释电元。 而且制成的两个电极化方向正好相反， 环境背景辐射对两个热释元件几乎具有相同的作用， 使其产生释电效应相互抵消， 于是探测器无信号输由。(4)一旦人侵入探测区域内，人体红外辐射通过部分镜面聚焦，并被热释电元接收， 但是两片热释电元接收到的热量不同， 热释电也不同，不能抵消，经信号处理而报警。(5)菲涅尔滤光片根据性能要求

3、不同，具有不同的焦距(感应距离)，从而产生不同的监控视场，视场越多，控制越严密。被动式热释电红外探头的优缺点：优点：本身不发任何类型的辐射，器件功耗很小，隐蔽性好。价格低廉。缺点：容易受各种热源、光源干扰被动红外穿透力差，人体的红外辐射容易被遮挡，不易被探头接收。易受射频辐射的干扰。环境温度和人体温度接近时，探测和灵敏度明显下降，有时造成短时失灵。抗干扰性能：1,防小动物干扰探测器安装在推荐地使用高度，对探测范围内地面上地小动物，一般不产生报警。2,抗电磁干扰探测器的抗电磁波干扰性能符合 GB10408 中 4.6.1 要求，一般手机电磁干扰不会引起误报。3.抗灯光干扰探测器在正常灵敏度的范围

4、内，受 3 米外 H4 卤素灯透过玻璃照射，不产生报警。红外线热释电传感器的安装要求：红外线热释电人体传感器只能安装在室内，其误报率与安装的位置和方式有极大的关系，正确的安装应满足下列条1.红外线热释电传感器应离地面 2.0-2.2 米。2 .红外线热释电传感器远离空调，冰箱，火炉等空气温度变化敏感的地方。3 .红外线热释电传感器探测范围内不得隔屏、家具、大型盆景或其他隔离物。4 .红外线热释电传感器不要直对窗口，否则窗外的热气流扰动和人员走动会引起误报， 有条件的最好把窗帘拉上。 红外线热释电传感器也不要安装在有强气流活动的地方。红外线热释电传感器对人体的敏感程度还和人的运动方向关系很大。

5、热释电红外传感器对于径向移动反应最不敏感， 而对于横切方向（即与半径垂直的方向）移动则最为敏感,在现场选择合适的安装位置是避免红外探头误报、 求得最佳检测灵敏度极为重要的一环。2.菲涅尔透镜2.1概述菲涅尔透镜多是由聚烯烧材料注压而成的薄片，镜片表面一面为光面， 另一面刻录了由小到大的同心圆。 菲涅尔透镜的在很多时候相当于红外线及可见光的凸透镜， 效果较好， 但成本比普通的凸透镜低很多。 菲涅尔透镜可按照光学设计或结构进行分类。 菲涅尔透镜作用有两个：一是聚焦作用；二是将探测区域内分为若干个明区和暗区，使进入探测区域的移动物体能以温度变化的形式在 PIR （被动红外线探测器）上产生变化热释红外

6、信号。2.2作用菲涅尔透镜利用透镜的特殊光学原理， 在探测器前方产生一个交替变化的“盲区”和“高灵敏区”， 以提高它的探测接收灵敏度。 当有人从透镜前走过时，人体发生的红外线就不断地交替从“盲区”进入“高灵敏区”， 这样就使接收到的红外信号以忽强忽弱的脉冲形式输入，从而强其能量幅度。菲涅尔透镜菲涅尔透镜， 简单的说就是在透镜的一侧有等距的齿纹， 通过这些齿纹，可以达到对指定光谱范围的光带通（反射或者折射）的作用。传统的打磨光学器材的带通光学滤镜造价昂贵。菲涅尔透镜可以极大的降低成本。典型的例子就是 PIRoPIR 广泛的用在警报器上。如果你拿一个看看，你会发现在每个 PIR 上都有个塑料的小帽

7、子。这就是菲涅尔透镜。小帽子的内部都刻上了齿纹。这种菲涅尔透镜可以将入射光的频率峰值限制到 10 微米左右（人体红外线辐射的峰值）。菲涅耳透镜可以把透过窄带干涉滤光镜的光聚焦在硅光电二级探测器的光敏面上，菲涅尔透镜不能用任何有机溶液（如酒精等）擦拭，除尘时可先用蒸储水或普通净水冲洗，再用脱脂棉擦拭。3.HowInfraredmotiondetectorcomponentsworkInfraredRadiationInfraredradiationexistsintheelectromagneticspectrumatawavelengththatislongerthanvisiblelight

8、.Itcannotbeseenbutitcanbedetected.Objectsthatgenerateheatalsogenerateinfraredradiationandthoseobjectsincludeanimalsandthehumanbodywhoseradiationisstrongestatawavelengthof9.4um.Infraredinthisrangewillnotpassthroughmanytypesofmaterialthatpassvisiblelightsuchasordinarywindowglassandplastic.Howeveritwil

9、lpassthrough,withsomeattenuation,materialthatisopaquetovisiblelightsuchasgermaniumandsilicon.AnunprocessedsiliconwafermakesagoodIRwindowinaweatherproofenclosureforoutdooruse.Italsoprovidesadditionalfilteringforlightinthevisiblerange.9.4uminfraredwillalsopassthroughpolyethylenewhichisusuallyusedtomak

10、eFresnellensestofocustheinfararedontosensorelements.PyroelectricSensorsThepyroelectricsensorismadeofacrystallinematerialthatgeneratesasurfaceelectricchargewhenexposedtoheatintheformofinfraredradiation.Whentheamountofradiationstrikingthecrystalchanges,theamountofchargealsochangesandcanthenbemeasuredw

11、ithasensitiveFETdevicebuiltintothesensor.ThesensorelementsaresensitivetoradiationoverawiderangesoafilterwindowisaddedtotheTO5packagetolimitdetectableradiationtothe8to14mmrangewhichismostsensitivetohumanbodyradiation.Typically,theFETsourceterminalpin2connectsthroughapulldownresistorofabout100Ktogroun

12、dandfeedsintoatwostageamplifierhavingsignalconditioningcircuits.Theamplifieristypicallybandwidthlimitedtobelow10Hztorejecthighfrequencynoiseandisfollowedbyawindowcomparatorthatrespondstoboththepositiveandnegativetransitionsofthesensoroutputsignal.Awellfilteredpowersourceoffrom3to15voltsshouldbeconne

13、ctedtotheFETdrainterminalpin1.ThePIR325sensorhastwosensingelementsconnectedinavoltagebuckingconfiguration.Thisarrangementcancelssignalscausedbyvibration,temperaturechangesandsunlight.Abodypassinginfrontofthesensorwillactivatefirstoneandthentheotherelementwhereasothersourceswillaffectbothelementssimu

14、ltaneouslyandbecancelled.TheradiationsourceFRESNELLENSTHERMALENERGYTYPICALCONFIGURATIONmustpassacrossthesensorinahorizontaldirectionwhensensorpins1and2areonahorizontalplanesothattheelementsaresequentiallyexposedtotheIRsource.AfocusingdeviceisusuallyusedinfrontofthesensorThefigurebelowshowsthePIR325e

15、lectricalspecificationsandlayoutinitsTO5package.Notethewideviewinganglewithoutanexternallens.infraredsourcemovementPIR325SENSITIVEAREA2ELEMENTSSPECTRALRESPONSE1411mOUTPUTVOLTAGEmvpp20NOISEuVpp20OFFSETVOLTAGEvolts1.0SUPPLYVOLTAGEvolts2,5-15OPERATINGTEMPc30-70TestConditionsforoutputvoltage:Supplyvolta

16、ge=5volts100Kloadresistorfrompin2to3IRsource=Handmoving6fromsensorThisisatypicalapplicationcircuitthatdrivesarelay.R10andC6adjusttheamountoftimethatRY1remainsenergizedaftermotionisdetected.DownloadPDFdrawing.BOTTOMVIEWFresnelLensAFresnellens(pronouncedFrennel)isaPlanoConvexlensthathasbeencollapsedon

17、itselftoformaflatlensthatretainsitsopticalcharacteristicsbutismuchsmallerinthicknessandthereforehaslessabsorptionlosses.FRESNELOurFL65FresnellensismadeofaninfraredtransmittingmaterialthathasanIRtransmissionrangeof8to14umwhichismostsensitivetohumanbodyradiation.ItisdesignedtohaveitsgroovesfacingIC1=L

18、M324ICZ=CW5MPIR=PIR325D1-D5=1N914R10KjohmsXCBmid=ONlimsRY1-coilvoHagerating=V+voflag0MOTIONDETECTORPLAMOCONVEXtheIRsensingelementsothatasmoothsurfaceispresentedtothesubjectsideofthelenswhichisusuallytheoutsideofanenclosurethathousesthesensor.Thelenselementisroundwithadiameterof1inchandhasaflangethat

19、is1.5inchessquare.Thisflangeisusedformountingthelensinasuitableframeorenclosure.MountingcanbestandmosteasilybedonewithstripsofScotchtape.Siliconerubbercanalsobeusedifitoverlapstheedgestoformacaptivemount.TheFL65hasafocallengthof0.65inchesfromthelenstothesensingelement.Ithasbeendeterminedbyexperiment

20、tohaveafieldofviewofapproximately10degreeswhenusedwithaPIR325Pyroelectricsensor.ThisrelativelyinexpensiveandeasyPyroelectricSensorandFresnelLenscanbeusedinavarietyofscienceprojects,robotsandotherusefuldevices.3.1FocusingdevicesforpyroelectricsensorsA.1PyroelectricinfraredsensorsA.2Firstwewilllookata

21、pyroelectricinfraredIRFRESNELLENSinstalllenswithgroovesfacingPIRfocallength_0,65_0.015thicknessOptimumtransmittanceinthe8to14urnregiontouseinfraredsensorandseehowitismadeandwhyafocusingdeviceisnecessary.Acommonlyusedpyroelectricinfraredsensorhastwosensingelementsinternallyconnectedinavoltagebuckingc

22、onfiguration.ApyroelectricsensorhasaninfraredfilterwindowthatadmitsIRwithinthe5to15micrometerwavelengthrange.Oneendofthetwoseries-connectedelementsinananalogsensorisconnectedtopin3thatisnormallygrounded.TheotherendconnectsinternallytothegateofaFieldEffectTransistorandtoaveryhighvaluepulldownresistor

23、.PowerisappliedtoFETPIRdrainpin1andtheoutputsignalcomesfromFEIsourcepin2whichusuallyconnectsthroughanexternalpulldownresistortogroundandtoanamplifier.Adigitalsensornotshownhere,includesinternalprocessingcircuitsandoutputsdigitalpulses.A.3ThesensorishousedinaTO5typepackage.Sensingelementsareeach0.039

24、inch(1mm)wideandarespaced0.039inch(1mm)apart.A.4Environmentalconditionssuchastemperaturechangesandsunlightwillaffectbothelementssimultaneouslyandwillproducethesameamountofoutputfromeachelementbutofopposingpolarityandwillthereforebecancelled.Thesensorwillonlyproduceachangeinitsoutputvoltagewhenoneofi

25、tselementsisexposedtoachangeinradiationandtheotherisnotexposed.AnIRemittingbodymovingacrossthefrontofasensorwillexposefirstone,thenbothandthentheothersensorEHvl&ixelement.Theoutputsignalwaveformfromananalogsensorshowsthatformotioninonedirection,firstapositive,thenzeroandthenanegativetransitionre

26、sults.Motionintheotherdirectionwillproducefirstanegative,thenzeroandthenapositivetransition.WhenalensisnotusedinfrontofasensorandanIRemittingbodyisclosetothesensor,aboutA.53or4feetanditmovesacrossthefrontofthesensor,theradiatedIRwillexposeoneelementmorethantheotherandavoltageoutputwillresult.However

27、,whentheIRemittingbodyisfurtherawayfromthesensoritsradiationpatternbecomesblurredandbothelementsareexposedmoreequally,resultinginnovoltageoutput.Thelimiteddetectionrangeisduetoalackofunequalexposure.Placingalensinfrontofthesensorextendsitsdetectionrange.A.6TheFresnellensA.7AFresnellensisaPlanoConvex

28、lensthathasbeencollapsedonitselftoformaflatlensthatretainsitsopticalcharacteristicsbutismuchthinnerandthereforehaslessabsorptionloss.AFresnellensisusuallythinandflexibleandisabout0.015inch(0.38mm)thickwithgroovesmoldedintoonesurface.n.r?joror.VFKThegroovesideofthelensusuallyfacesthePIRsensor.AFresne

29、llensbothcapturesmoreIRradiationandfocusesittoasmallpoint.ThisfocalpointmovesacrossthesensorastheIRsourcemovesandexposesoneelement065FRESNELg-lens廿曲LEMSgroowsf&cinqPRatatime.AFresnellenscanextenddetectionrangetoabout100feet.AFresnellenswillgivethebestpossibleperformance,howeverotherdevicescanbeu

30、sedtoextendrange.Althoughthefollowingdevicesmaynotfitthedescriptionofalens,wewillcallthemlensesanyway.ThisdiagramshowsIRexposingbothelementsequallywhennolensisused.ShadowlensSincesimultaneousexposureofbothelementsisthecauseoflimiteddetectionrange,allweneedissomemethodofpreventingtheIRfromexposingbot

31、helementssimultaneouslyastheIRemittingbodymovesacrossthefrontofthesensor,evenatgreaterdistancesfromtheTO=If/JLAZIIC.O：9inFnwmADEfchDSPACEDQ-.N口imn)sensor.Thesensorelementsare0.039inch(1mm)wideandarespaced0.039inch(1mm)apart.IfweplaceathinverticalstripofIRopaquematerialabout0.060inch(1.5mm)widecenteredinfrontofthesensorwecanpreventsomeoftheIRfromstrikingthesurfaceofthesensorbyproducingashadow,eveniftheIRemittingbodyisatagreaterdistancefromthesensor.ThefollowingfigureshowssuchabafflebutinthisexampletheIRstillexposesbothelementsequally.Byplacingabaffleormaskinfrontoft