Johdanto
In1666,BritishscientistNewtonfirstrevealedthechromaticnatureoflightandthesecretofcolor.Heusedexperimentstoshowthatsunlightisamixedlightofvariouscolors,andfoundthatthecoloroflightdependsonthefrequencyoflight.
Värirenkaassa oleva numero ilmaisee vastaavan värivalon taajuuden. Taajuusyksikkö on terahertsiä (THz) ja aallonpituustuntinanometriä (nm).Värirenkaan kahdessa vastakkaisessa sektorissa ovat symmetrisiä toistensa suhteen. Täydentävä väri.Esimerkki,täydennysväri.
Themainnaturallightsourceofvisiblelightisthesun,andthemainartificiallightsourceisincandescentobjects(especiallyincandescentlamps).Thevisiblespectrumtheyemitiscontinuous.Thegasdischargetubealsoemitsvisiblelight,anditsspectrumisdiscrete.Variousgasdischargetubesandfiltersareoftenusedasmonochromaticlightsources.
Alue
Electromagneticwaveswithdifferentfrequenciescausedifferentcolorperceptionsinhumaneyes.
Punainen | 385 ~ 482 THz | 780~622nm | |
Oranssi | 482 ~ 503 THz | 622-597 nm | |
Keltainen | 503-520 THz | 597~577nm | |
vihreä | 520-610 THz | 577~492nm | |
sininen, indigo | 610-659 THz | 492-455 nm | |
Violetti | 659-750 THz | 455-400 nm |
Thefrequencyofvisiblelightis3.8×1014~7.5×1014Hz(380~750THz).
Ominaisuudet
Throughresearch,itisfoundthatthecolorlightalsohasthefollowingcharacteristics:
1.Thecomplementarycolorsaremixedinacertainproportiontoobtainwhitelight.Forexample,bluelightandyellowlightaremixedtogetwhitelight.Inthesameway,themixtureofcyanlightandredlightisalsowhitelight.
2.Anycoloronthecolorringcanusethetwokindsofmonochromaticlightsonitsadjacentsides,andcanevenbecopiedfromthetwokindsofmonochromaticlightsofthenextneighbors.Ifyellowlightandredlightaremixedtogetorangelight.Itismoretypicalthatredlightandvihreälightmixtobecomeyellowlight.
3.Ifyouchoosethreeindependentmonochromaticlightsonthecolorring.Itcanbemixedintovarioustonesthatmayappearindailylifeindifferentproportions.Thesethreemonochromaticlightsarecalledthreeprimarycolors.Thethreeprimarycolorsinopticsarered,vihreä,andblue.Itshouldbenotedherethatthethreeprimarycolorsofthepigmentarecyan,magenta,andyellow.However,thechoiceofthethreeprimarycolorsiscompletelyarbitrary.
4.Whenthesunlightilluminatesanobject,thelightofacertainfrequencyisabsorbedbytheobject,andthecolor(reflectedlight)displayedbytheobjectisthecomplementarycolorofthelight.Ifthesunshinesontheobject,iftheobjectabsorbsthevioletlightof435~400nm,theobjectwillappearyellow-vihreä.
Näkyvä valosäteily
Näkyvä valosäteilygenerallyreferstotheradiationinthe0.78~0.4micronbandinthesolarradiationspectrum,consistingofred,orange,yellow,vihreä,andblueItiscomposedofsevencolorsoflightsuchas,indigoandpurple.Itisthenecessaryandeffectivesolarradiationenergyforvihreäplantstocarryoutphotosynthesis.Thevisiblelightradiationreachingthegroundsurfacevarieswithatmosphericturbidity,sunheight,cloudcoverandweatherconditions.Näkyvä valosäteilyaccountsforabout45-50%ofthetotalradiation.
Sovellus
Kaukotunnistustekniikka
Näkyvä valoremotesensing(visiblespectralremotesensing)meansthattheworkingbandofthesensorislimitedtotherangeofvisiblelight(0.78~0.4microns)RemoteSensingTechnology.
Thevisiblelightrangeoftheelectromagneticspectrumisbetween0.78and0.4microns,whichisthemostcommonlyusedworkingbandintraditionalaerialphotographyreconnaissanceandaerialphotographysurveyingandmapping.Becausethecolorsensitivityrangeofphotosensitivefilmisjustinthisfrequencyrange,black-and-whitefull-colororcolorimageswithhighgroundresolution,interpretationandmapdrawingperformancecanbeobtained.However,duetotheextremelimitationsofthesun'silluminationconditions,coupledwiththesuccessiveemergenceofinfraredphotographyandmulti-bandremotesensing,visiblelightremotesensinghasextendedtheworkingbandtothenear-infraredregion(approximately0.9microns).Theimagingmethodhasalsodevelopedfromasinglephotographicimagingtoincludeblack-and-whitephotography,infraredphotography,colorphotography,colorinfraredphotography,multi-bandphotographyandmulti-bandscanning,anditsdetectioncapabilitieshavebeengreatlyimproved.Näkyvä valoremotesensing,markedbytheapplicationofframe-typeaerospacecameras,hasgreatdevelopmentpotentialforspacephotogrammetry.
Viestintäteknologia
Näkyvä valocommunicationtechnologyisanewvihreäinformationtechnologythatusestherapidresponsecharacteristicsofLEDstoachievewirelesshigh-speeddatatransmission.Thedigitalsignalismodulatedtothepowerline,andthevisiblelightflashesquicklythroughthecommunicationmoduleinstalledintheLEDlamptorealizethetransmissionofinformation.Thiskindoffastflickerreaches300Mbit/s,andthehumaneyecannotperceivethiskindofflicker.Second,theflashinglightisreceivedbythephotosensitivedeviceatthereceivingend,andthedemodulationistheinformationthatthetransmittingendwantstotransmit.AsoneoftheInternetofThingstechnology,visiblelightcommunicationtechnologyistoprovidelightingequipmentwith"wirelessrouters","communicationbasestations","networkaccesspoints"andeven"wirelessrouters","communicationbasestations","networkaccesspoints"andeven"underthepremiseofnotaffectingnormallighting."ThefunctionofGPSsatellites.
Pilvikartta
Thesatelliteobservationinstrumentsensesthereflectionofthegroundandcloudsonthesuninthevisiblelightband,anddisplaysitasaplaneimage,whichisvisiblelightcloudmapb>.Thedegreeofblackandwhiteoftheimagerepresentsthealbedoofthegroundandclouds,whitemeanshighalbedo,andblackmeanslowalbedo.Generallyspeaking,thethickerthecloud,thebrighteritsbrightness.Ifthelightingconditionsofthesunarethesame,thewaterdropletcloudisbrighterthantheicecrystalcloudforthesamethickcloud.Forexample,largeandthickclouds,especiallycumulonimbusclouds,aredensewhite;medium-thickclouds(cirrostratus,altostratus,fog,stratus,cumulus,etc.)arewhite;thinandsmallcloudareasonthecontinent(Suchascumuluscloudsonasunnyday)areoff-white,etc.
Näkyvä valo
Yhteinen valolamppu sisältää hehkulamput, halogeenilamput, loistelamput, energiansäästölamput, LED-lamput, korkeapaineiset natriumlamput, metallihalogenidilamput, elektrodittomat lamput, neonlamput jne.
Thefollowingintroducestheworkingprinciplesofseveralcommonvisiblelightlampstoillustratethevariousfrequenciesofvisiblelightradiationthatthistypeoflampsmayproduceduringdailyuse:
1.Incandescentlamps:Itsstructureistoputthefilament(singlespiralfilamentordoublespiralfilament)intotheglassshell,andaddalampcap.Thefilamentisspiralinordertoreducetheevaporationoftungsteninthefilamentandprolongitsservicelife.Generally,itisfilledintheglassshell.Theargon-nitrogenmixtureisalsousedtoreducetheevaporationoftungsteninthefilament.Whenthelampisconnectedtothecircuit,thecurrentflowsthroughthefilament,andthecurrentproducesathermaleffect,causingtheincandescentbulbtoemitcontinuousvisiblelightandinfrared.Thisphenomenoncanbenoticedwhenthefilamenttemperaturerisesto700K.ThefrequencyofthethermalradiationisfromclosetoInfrared(380THz,780nm)graduallyrisestoaboutultraviolet(750THz,400nm).Theincandescentlampisalowcolortemperaturelightsource,thecolortemperatureisgenerally2400~2900K,thecolorrenderingisbetter,thecolorrenderingindexis99~100.However,duetothehightemperatureofthefilamentduringoperation,mostoftheenergyisconsumedintheformofinfraredradiation,sotheservicelifeisshort,generallynotexceeding1000h.Amongallelectriclightingproducts,incandescentlampshavethelowestefficiency.Onlyabout2%oftheenergycanbeconvertedintolightenergy.Althoughthelightefficiencyoftheincandescentlampislow,thelightcolorandlightcollectionperformanceareverygood,anditistheelectriclightsourcewiththelargestoutputandthemostwidelyused.
2.Halogenlamp:Basedontheincandescentlamp,asmallamountofhalogenelementisaddedtothefillinggastoformanefficientsmalllightsource.Ordinaryglassshellsarealsochangedtoquartzglass,hardhighsilicaglassoraluminateglasstoovercomehightemperatures.Halogenlampshavethecharacteristicsofhighluminousefficiencyandlonglife,andthereisa"tungstenhalogencycle"inthehalogenlamp,thatis,acyclicchemicalreaction.Halogenlampsandincandescentlampsarebothheatradiationlightsourcesandradiatealotofheat.However,theintensityoflightemittedbyhalogenlampsismuchhigherthanthatofincandescentlamps,andtheenergyconsumptionisreducedbyabout1/3.Thelightemittedbythehalogenlampcontainsultravioletcomponents,whicharedividedintothreewavelengthbands:UVA,UVB,andUVC,andUVBandUVChaveableachingeffectonthesubject.WhetherthehalogenlampwillproduceUVBharmfultothehumanbody,UVCdependsontheglassshellofthehalogenlamp.
3.Fluorescentlamp:adischargelampwithlow-pressuremercuryvaporatthecathode.Theultravioletlightreleasedbythedischargeisconvertedintovisiblelightbythereflectionofthephosphor.Thedouble-spiralortriple-spiraltungstenfilamentisusedonthesurfaceofthefilament.Coatedwithelectronemissionmaterialstoformtheemitter.Theglasstubeisfilledwithamixtureofargon,krypton,andneon,andamalgam,andtheinnerwalloftheglasstubeiscoatedwiththreeprimarycolorphosphors.Itsworkingprinciple:theballastgeneratesapulsevoltagetopreheatthefilament,andtheelectronemissionmaterialonthecathodeisactivatedtogenerateelectrons.Theelectronscollidewiththemercuryatomsinthetubetogenerate253.7nmand185nmultravioletrays.Themainpeakis253.7nm,accountingforabout70%to80%ofthetotalradiantenergy;thesub-peakvalueis185nm,accountingforabout10%ofthetotalradiantenergy.Ultravioletrayspassthroughtheinnerwalloftheglasstubecoatedwithphosphortorefractvisiblelight.Becauseoftheuseofthreeprimarycolorphosphorsandultravioletlightcomponents,thefluorescentlampspectrumhasmultiplesmallspikes,andthereismercuryvaporwithapressureofabout0.8Pa,whichisdischargedundertheactionofanelectricfield,andthevalenceelectronsofmercuryatomsareremovedfromtheoriginalstate.Excitedbecomesanexcitedstate.Atthesametime,itspontaneouslyreturnstothegroundstateinanexcitedstate,convertingvalenceelectronsintoelectromagneticradiationenergy,andradiating353.7nmultravioletrays,andthereareabout10%85nmhigh-frequencyultravioletrays.Thephosphorontheinnerwalloftheglasstubeabsorbs353.7nmultravioletlightandconvertsitintovisiblelight.Sincemostoftheelectricenergyconsumedbyfluorescentlampsisusedtogenerateultravioletrays,theluminousefficiencyoffluorescentlampsismuchhigherthanthatofincandescentlampsandtungstenhalogenlamps,andisamoreenergy-savinglightingsource.Whenthefluorescentlampisworking,thetemperatureofthefilamentisabout1160K,whichismuchlowerthantheworkingtemperatureoftheincandescentlamp,whichis2400~2900K,soitsservicelifeisgreatlyextended,reachingmorethan5000h.Anotherfeatureoffluorescentlampsisthattheyhavegoodcolorrendering,haveideallightingeffectsforcolorfulobjectsandenvironments,andhavelowlightdecay.Therefore,theyarewidelyused.
4.LEDlamp:isasolid-statesemiconductorcomponentthatcanconvertelectricalenergyintovisiblelight,thatis,light-emittingdiodes,whichdirectlyconvertelectricalenergyintolightenergy.ThecorecomponentoftheLEDisasemiconductorchip.Oneendofthechipisattachedtothebracket,oneendisthenegativepole,andtheotherendisthepositivepoleconnectedtothepowersupply.Theentirechipisencapsulatedbyepoxyresin.AsingleLEDlampbeadonlyworksatalowvoltageofabout3Vandalowcurrentofaboutafewmilliamps.Drivecircuit),maketheintegratedmultipleLEDlampbeadsworkunderthemainspower,andtheninstallthelampholder.Theself-ballastedLEDlampreferstoanLEDlampwithalampcapthatcanintegratestableignitioncomponentsintoone,andcaneasilyreplacetraditionalincandescentlamps.CommonlyusedwhiteLEDlightingisafluorescentlightsourceexcitedbyblueLEDs.Exceptforapartoftheheatdissipatedtoelectroniccomponents,mostofthewhitelightenergyofLEDlightingcanbeconvertedintovisiblelight,anditsluminousefficiencycanreach50~200lm/W.Itscharacteristicsaresimplestructure,lowcost,longservicelife,highluminousefficiency,andresistancetobreakage.