Introduction
[weatherforecast]Pre-estimationandforecastofweatherchangesinacertainperiodinthefuture.Weatherforecastingisanimportantmeansformeteorologicalworktoservethenationaleconomyandnationaldefenseconstruction.Weatherforecastsaredividedintoforecastranges,includingregionalweatherforecastsandlocalweatherforecasts.Accordingtotheneedsofserviceobjects,therearedailypublicweatherforecastsandprofessionalweatherforecasts.Accordingtothelengthoftime,thereareshort-term,medium-termandlong-termweatherforecasts.TheMeteorologicalObservatorypublishesweatherforecastsinatimelyandaccuratemannerthroughvariouschannels,especiallydisastrousweatherforecasts,whichplayanimportantroleinprotectingpeople'slivesandpropertyandpromotingeconomicdevelopment.Thetechnologyofweatherforecastingdevelopedrapidlywiththedevelopmentoftelegraph.Bytheearly1950s,weatherforecastshadbeenbasedonsynopticprinciples.Withthedevelopmentofcomputingtechnologyanddetectiontechnology,inadditiontotheconventionalweatherchartmethodcombinedwithmathematicalstatisticstomakeforecasts,meteorologicalradarandsatellitedetectiondataareappliedtotheforecastingbusiness,andnumericalforecastingmethodshavebeendevelopedatthesametime.Thismethodpredictsthephysicalprocessoftheatmospherebydeterminingtheprinciplesofconservationofatmosphericmass,energyandmomentum,andsignificantlyimprovesthequalityofweatherforecasts,therebypromotingtheobjectivequantificationofweatherforecasts.
Muinaiset ennusteet
Muinaisen kiinalaisen sääennusteet
"Kohtoteorian" mukaan auringonnousu, auringonlasku ja laskuvesi ovat toistuvia luonnollisia kiertokulkuja. Ihmisetvoivat tehdä tarkempia ennusteita useille vuosillekymmenkertaisillemuutoksille. Tällä hetkellä ihmiset odottavat tietävänsä säännöllisyytensä etukäteen.
Sinceancienttimes,Chineseintellectualshavepaidattentiontothepredictionofastronomy,earthquakeandmeteorology.TheancientthinkerDongZhongshuputforwardtheslogan"Quthepeoplestretchouttheruler,andtherulerstretchesoutthesky".Thefirstsentenceistoobeytheemperor.ThesecondsentenceisfortheemperortolistentoGod'swill.Providencerestrictedtheemperor'sactions.Mostoftheseprovidencescomefromtheignoranceofthesky(suchassolareclipses)andtheground(suchasearthquakes),andtheunpredictabilityofextremeweatherandabnormalclimates,suchaslightning,drought,floods,fires,andlocustdisasters.Ignoranceofnaturaldisasters(theemperor)andthelower(subjects)openedthedoorforthesubjectstoexpresstheiropinions.Intheearlydays,astronomyandmeteorologywerenotseparated.Bothastronomyandmeteorologymustbeobservedandforecasted.Threethousandyearsago,mycountry’sOracleincludedrecordsoftheactualweather,includingwind,clouds,rainbows,rain,snow,frost,clouds,tornadoes,andthunderstorms.Afteralargenumberofweathereventshavebeenrecordedinwriting,someintellectualsfinallyhaveanunderstandingoftheclimate.Inancientmycountry,observingastronomyandweather,formulatingcalendars,understandingandpredictingclimate,theclearestusewastoarrangeagriculturalproduction,sacrificesandotheractivities.Theinscriptionsalsoreflectthatpeoplealreadyhaverequirementsforpredictingweatherconditions,whichareallinlinewiththeneedsofagriculturalproductionatthattime.AsfarastheSpringandAutumnPeriod,theancientssetfoursolarterms:Mid-Spring,Mid-Summer,Mid-AutumnandMid-Winter.Continuousimprovementandperfectioninthefuture,bytheQinandHanDynasties,thetwenty-foursolartermshavebeenfullyestablished.
WeatherforecastforancientWesterners
Weatherforecastisanappliedscience.Theachievementsofscienceoriginatefromthought.Around340BC,theancientGreekphilosopher,scientistandeducatorAristotle(384BCto322BC)wrotetheworld'searliestmonographonmeteorology,"GeneralMeteorology".Thebookdescribesthecausesanddistributionofhurricanes,foehnwindsandwinds,atmosphericlightpatternssuchashalos,rainbows,andthunderandlightning,theformationofclouds,rain,hailandhaze,andclimatechange.Aristotlesystematicallysortedoutallthepreviousmeteorologicalthoughtsandexperiences,andputforwardhisowninsightsandtheoriesonvariousweatherphenomena,makingitasystematicscience—ancientmeteorology,namelyTheideologicalbasisofancientweatherforecasting.Thedescriptionoflocalweatherobservationsatthattimedeterminedthattheweatherforecastwasalsolocal.Aristotledividedthelocalskyintotwoupperandlowerparts:oneisthecelestialdomain-theareaoutsidethemoon'sorbit,andtheotheristhearea-therangefromthemoon'sorbittotheground.Theformeristhescopeofastronomyobservationandresearch,whiletheatmosphericphenomenaoccurringinthelatterbelongtotheresearchobjectofmeteorology.Hebelievesthatdryandwarmemissionsconstitutewind,anddampandcoldemissionsconstitutewatervapor,whichisthesourceofrain.Therefore,airisthemediumofwatervaporandwind.Clouds,rain,snow,frost,anddewareallcausedbychangesinairtemperature.Forming.TheauthorityofAristotledominatedwesternmeteorologicaltheoryfortwothousandyears.Beforetheendofthe17thcentury,allwesternmeteorologicalworksandtreatiseswerenotabletoescapetheinfluenceofAristotle'smeteorology.
Developmenthistory
Earlyweatherforecast
Numericalvaluesarethelanguageofscience.Weatherforecastingisinseparablefromthequantitativeobservationofatmosphericmotionbyinstruments.Wecansettheinventionandapplicationofmeteorologicalinstrumentsasthestarttimeofearlyweatherforecasting.
Inthe15thcentury,theWestinventedtheplatenanemometer,whichcanquantitativelymeasurethespeed(energy)ofatmosphericmotionforthefirsttime.Fromthe17thtothe18thcentury,scientistssuccessivelyinventedvariousinstrumentsforquantitativelymeasuringweatherphenomena,markingthebeginningofanewperiodofdevelopmentforthedetectionmethodsofmeteorologicalscienceresearch.BritishphysicistHooke(1635-1703)inventedthehygrometer.In1606,Galileoinventedthethermometer.In1639,Galileo'sdiscipleBenedettoCastelliinventedtheraingauge.In1644,Torricelliinventedthebarometer.In1774,Cotteinventedthehygrometer.Inthemiddleofthe18thcentury,peoplebegantoattempthigh-altitudeexploration.In1748,BritishA.Wilsonandothersbegantocarrythermometerswithkitestoobservelow-altitudetemperature.In1752,AmericanscientistB.Franklinusedkitesandothertoolstodetectandstudythepropertiesofelectricchargesinthunderstormclouds.In1783,France'sJ.A.C.Charlieusedhydrogenballoonsforthefirsttimetocarrytemperature,pressureandotherself-recordingmeteorologicalinstrumentstomeasuretemperatureandpressureatvariousaltitudes.Theseearlierhigh-altitudesurveysareusedtomeasurethetemperatureandairpressureatvariousaltitudesandotherelementsforfutureresearchonlargemeteorologicalinstruments.
Withtheinventionofmeteorologicalinstrumentsandtheestablishmentofobservationnetworks,aswellasthedevelopmentoffluiddynamicstheory,itispossibletoestablishatheoreticalsystemforweatherforecasting.In1820,Germany'sH.W.Brandesusedthemeteorologicalobservationdatapublishedinthe"JournaloftheBaladinMeteorologicalSociety"tofillintherecordsofthepressureandwindatthesametimein1783onthemap,makingittheworld'sfirstweathermap.Thispioneeringworkhastakenasolidstepforwardinanalyzingtherelationshipbetweenairpressure,windandweather,andestablishingaconceptualmodeloftheweathersystem.Thebirthoftheweatherchartisasignofmodernmeteorologicaltheoreticalresearchandmodernweatherforecastingpractice.Theinventionofthetelegraphhasprovidedconditionsfortherapidtransmissionofmeteorologicalobservationdataandtheconcentrationofinformationinvariousplaces,makingitpossibletodrawreal-timeweathermaps.In1851,J.GlescheroftheUnitedKingdomusedtelegraphtotransmitdataanddrewinstantaneousweathermapsforpracticalapplications.
Modernweatherforecast
Inthepasthundredyears,somemeteorologicalleadershavemadefulluseofthecombinationoflarge-scalegroundandupperairobservationdataandmathematicalmethods,whichhasstronglypromotedthedevelopmentofweatherforecasttheory.Andtheimprovementoftheweatherforecastservicelevel.OneisthecirculationtheoryandcyclonewavemodeloftheNorwegianschool,andthesecondisthelongwavetheoryoftheChicagoschool,whichhasmadeoutstandingcontributionstothedevelopmentofmeteorologicalsciencerecognizedworldwide.
ThecorefigureoftheNorwegianSchoolisV.Peyknis(1862-1951).Hehasbeenunremittinglytransformingmeteorologyfromrandomobservationaldatacollectionandaccidentalspeculativeforecastingtorigorousscience,andiscommittedtoimprovingtheaccuracyofweatherforecastsandlong-termweatherforecasts.Hiswishwastotransformmeteorologyintoanauthoritativediscipline,andthiswishwasrealizedwhenheworkedattheBergenSchoolofMeteorology.Military,agriculture,aviation,andfisherieshavequicklybecomeindustriesthatrelyonPeyknis’researchresults.Attheendofthe19thcentury,heputforwardarevolutionaryideaofapplyingtheprinciplesoffluidmechanicsandthermodynamicstoatmosphericmotion.Hisimportantachievementsinclude:in1897,hestudiedthecirculationmovementintheatmosphereandintroducedtheconceptofforcetubeforthefirsttime;in1904,heproposedtheconceptofdigitalweatherforecast;in1910,heproposedtodrawstreamlinesontheweathermaptorepresentthehorizontalmovementoftheair.Italsoanalyzestheconvergenceanddivergencezones;in1918,thedifferencebetweencoldandwarmfrontsinalow-pressureweathersystemwasdiscovered,andtheconceptofcoldandwarmfrontswasestablished,andFrontwasthenameoftheinterfacebetweenthecoolingandheatingmasses.
ThereisalsoacorefigureoftheNorwegianschool,cloudphysicistBergeron,whonotonlycontributedtothephysicsofclouds,butalsomadeachievementsintheclassificationofweatherconditions.Hesystematicallysortedoutthevariousdataheobservedandcollected,andin1919proposedthetheoryofthecycloneimprisonmentstage,whichenrichedthecyclonelifehistorymodel.Inhisdoctoraldissertation,healsoproposedconceptssuchasairmassclassification,frontalzone,andfrontogenesis,whichmadeimportantcontributionstoweatheranalysisandforecasting.
ChicagoSchoolbeganbrewinginthe1930s,formedandreacheditspeakinthe1940s,andcontinuedtoprosperinthe1950sand1970s.C.G.Robes(1898-1957),thecorefigureoftheChicagoSchool(orAmericanSchool),discoveredlongwavesonhigh-altitudeweathercharts.In1939,heproposedthelong-wavedynamics,derivedthepotentialvorticityequationfromthis,andfoundedthelong-wavetheory.Inthe1940s,theChicagoSchoolunderhisleadership,includingE.HPalmenandothers,confirmedthestructureandchangesofhigh-altitudewesterlyjetsandlongwaves,aswellastheirrelationshipwithcyclonewavesontheground.RossbyandtheChicagoSchool’smajorcontributiontoweatherforecastingisthe"RosbyWave",alsoknownasthe"AtmosphericLongWave".TheworkoftheChicagoSchoolhasstrengthenedtheconnectionbetweensynopticsandthermodynamicsanddynamics,enrichedthephysicalfoundationofweatheranalysisandforecasting,andprovidedtheoreticalbasisforthestudyoflarge-scaleatmosphericmotion,andpromotedthedevelopmentandapplicationofnumericalweatherprediction.
Modernweatherforecast
Modernweatherforecastismarkedbythegradualreplacementofconventionalweathermapforecastswithmoderndetectiontechnologies(weathersatellitesandweatherradars)andnumericalweatherforecastmodelssupportedbyhigh-speedcomputers.Theapplicationofthesetechnologiesandmethodsinweatherforecastingroughlybeganinthe1950s.
Forecastingmethods
Doublestations
Beforethe17thcentury,peoplemadeweatherproverbsbyobservingthechangesincelestialandphysicalphenomenatopredictthelocalweatherinthefuture.Afterthe17thcentury,meteorologicalobservationinstrumentssuchasthermometersandbarometersappearedoneafteranother,andgroundmeteorologicalstationswereestablishedoneafteranother.Atthistime,weatherforecastsweremainlybasedonchangesinsingle-stationairpressure,temperature,wind,andclouds.
Weathermap
In1851,theUnitedKingdomfirsttransmittedobservationdataviatelegram,drawnitintoagroundweathermap,andmadeweatherforecastsbasedontheweathermap.Sincethe1920s,airmasstheoryandpolarfronttheoryhavebeenappliedtoweatherforecasting.Inthe1930s,theinventionofradiosondes,theemergenceofhigh-altitudeweathermaps,andthewideapplicationoflong-wavetheoryinweatherforecastinghaveadvancedtheanalysisofweatherevolutionfromtwo-dimensionaltothree-dimensional.Inthelate1940s,theapplicationofweatherradarprovidedaneffectivetoolforforecastingprecipitationandsevereweathersuchastyphoons,heavyrains,andseverestorms.
Numericalweatherforecasting
Numericalweatherforecastingusesatmosphericmotionequationstointegrateequationsundercertaininitialandboundaryconditionstoforecastfutureweather.In1921,Richardsonfirsttriedtousenumericalmethodstoforecasttheweather.Becauseofthehugeamountofcalculationwork,heorganizedalotofmanpoweranddesigneddetailedcalculationtablestocomplete.However,theforecastresultswereseriouslyinconsistentwiththeactualatmosphericchanges.Thereasonwasthattheeffectsofhigh-frequencywavesintheatmospherewerenothandledproperly.In1950,Charneyusedtheworld'sfirstcomputerENIACtosuccessfullyproducea24-hournumericalforecastbasedontheatmosphericmotionequationsafterfilteringouthigh-frequencywaves.Withthedevelopmentofcomputertechnology,theadvancementofobservationmethods,andthedeepeningofunderstandingofatmosphericphysicalprocesses,numericalweatherpredictionhasmadegreatprogressandhasbecomethemainmeansofweatherforecasting.Especiallysincethelaunchofmeteorologicalsatellitesinthe1960s,thesatellite'sdetectiondatahavemadeupforthelackofmeteorologicaldatainareassuchasoceans,deserts,polarregions,andplateaus,whichhassignificantlyimprovedthelevelofweatherforecasting.
Forecastmethod
Situationforecast
Itistoforecastthegenerationanddisappearance,movementandintensitychangesofvariousweathersystemsinacertainperiodoftimeinthefuture.Itisthebasisofmeteorologicalelementforecasting.Situationforecastingmethodscanbedividedintotwocategories:oneisnumericalforecastingmethods,thatis,directlyintegratingatmosphericequationsorsimplifiedequations,andforecastingthefuturepressurefield,temperaturefield,andwindfieldbasedontheresults;theotherisWeatherchartmethod.Thelatterhasthefollowingmethods:
1.Eempiirinen ekstrapolointimenetelmä
alsoknownasthetrendmethod,isbasedonthepastmovementpathandintensitychangetrendofvariousweathersystemsontheweathermaptoinfertheirfuturelocationandintensity.Thismethodiseffectivewhenthereisnosuddenchangeinthemovementandintensityoftheweathersystemorwhenthereisnonewbirthordeathoftheweathersystem;however,whenthereisasuddenchangeorwhenthereisanewbirthordeathoftheweathersystem,theforecastisoftennotinlinewithreality.
2.Samankaltaisen tilanteen menetelmä
Alsoknownasmodelmethod,itistofindsomesimilarweathersituationsfromalargenumberofhistoricalweathermapsandsummarizethemintocertainpatterns.Ifthecurrentweathersituationissimilartotheprevioussituationofacertainmodel,theforecastcanbemadewithreferencetothelaterevolutionofthemodel.Sincesimilarityisalwaysrelative,itisimpossibletobeexactlythesame.Therefore,errorsoftenoccurinthismethod.
3.Tilastotietojen menetelmä
Alsoknownascorrelationmethod,ituseshistoricaldatatocalculatetheoccurrence,developmentandmovementofvariousweathersystemsindifferentseasonsinhistorytoobtaintheiraveragemovingspeedandfindForecastindicators(suchascyclonegeneration,typhoonturningindicators,etc.)forforecasting.Thismethodcannotbeappliedtoexamplesthathavenotappearedinhistoryormovedveryfastandveryslowly.
4.Fysikaalinen analyysimenetelmä
Firstly,itanalyzesthephysicalfactorsoftheweathersystem'sgenerationanddisappearance,movementandintensitychanges,andthenmakesweatherforecastsonthisbasis.Thismethodusuallyhasbetterresults.However,whenthesimplificationsandassumptionsoftheequationsofmotionthatreflectthesephysicalfactorsdonotconformtoreality,theyoftencauseforecasterrors,orevendeviatefarfromtheactualsituation.
Theabovefourmethodshavetheirownadvantagesanddisadvantages.Whenusingthem,theyneedtocomplementeachother,learnfromeachother'sstrengthsandmakeupfortheirweaknesses,andconsidercomprehensivelytoobtainbetterresults.
Elementtiennuste
Tämä ennustaa lämpötilan, tuulen, pilvien, sateiden ja sääilmiöiden muutoksia tietyllä ajanjaksolla tulevaisuudessa. Tilanneennuste perustuu elementtiennusteeseen. Elementtien ennustamiseen on useita tapoja:
1.Empiirinen ennustemenetelmä
Basedontheweathermapsituationforecast,accordingtothefuturepositionandintensityoftheweathersystem,forecastthefutureweatherdistribution.Forexample,whenthelowpressuremovesandisstrengthened,itcanbeforecastedthattherewillberainyweatherorheavierprecipitationinthefuture.Theaccuracyofthismethoddependstoalargeextentontheexperienceoftheforecaster,andbecausetheweathersystemandweatherphenomenadonotcorrespondone-to-one,theforecasteffectisnotstableenough.
2. Tilastolliset ennustemenetelmät
Analyzehistoricalweatherdata,seekthecorrelationbetweenchangesinatmosphericconditionsandpreviousmeteorologicalfactors,useregressionequationsandprobabilityprinciplestoscreenforecastfactorsandestablishforecastequations.Gettherequiredforecastvalue.Theeffectofthismethodmainlydependsonthecorrectchoiceoffactors.
3.Dynaamiset tilastot
Thefuturemeteorologicalparameterscalculatedbynumericalforecastingmethodsareusedasforecastfactors,andasetofforecastformulasareobtainedbyregressionequationstomakeelementforecasts.Withtheimprovementofthenumericalmodel,theaccuracyofthismethodmayincreasesteadily.
Ennusteprosessi
Nykyaikaisessa sääennusteessa on viisi osaa:
1.Tietojen kerääminen
title="Weatherpeg">otsikko
ThemosttraditionaldataisonthegroundOrdatasuchasairpressure,temperature,windspeed,winddirection,humidity,etc.collectedbyprofessionals,enthusiasts,automaticweatherstationsorbuoysonthesea.TheWorldMeteorologicalOrganizationcoordinatesthetimingofthesedatacollectionsandsetsstandards.Thesemeasurementsaredoneeveryhour(METAR)oreverysixhours(SYNOP).
Datafrommeteorologicalsatellitesisbecomingmoreandmoreimportant.Meteorologicalsatellitescancollectdatafromallovertheworld.Theirvisiblelightphotoscanhelpmeteorologiststoexaminethedevelopmentofclouds.Theirinfrareddatacanbeusedtocollectthetemperatureofthegroundandcloudtops.Bymonitoringthedevelopmentofthecloud,thewindspeedanddirectionattheedgeofthecloudcanbecollected.However,becausetheaccuracyandresolutionofmeteorologicalsatellitesarenotgoodenough,grounddataisstillveryimportant.
2.Tietojen assimilaatio
Thedatacollectedintheprocessofdataassimilationiscombinedwiththedigitalmodelusedforforecastingtogeneratemeteorologicalanalysis.Itisthebestestimateoftheatmosphericstate.Itisathree-dimensionalrepresentationoftemperature,humidity,pressure,windspeed,andwinddirection.
3. DataWeather
Calculatethechangesoftheatmosphereovertimeaccordingtotheresultsofphysicsandfluidmechanics.
4.Tulostenkäsittely
Theoriginaloutputcalculatedbythemodelgenerallyneedstobeprocessedbeforeitcanbecomeaweatherforecast.Thesetreatmentsincludeusingstatisticalprinciplestoeliminatedeviationsinknownmodels,ormakingadjustmentswithreferencetothecalculationresultsofothermodels.
5. Tuotantoprosessi
Accordingtothedataprovidedbyrelevantdepartments,makeachartofthenationalweathersituationonthecomputer(itisthebackgroundpictureoftheweatherforecastprogram);thehoststandsinfrontofabluescreen"Pointandpoint",explaintheweather(howtograspthelocationofeacharea,thehosthasonlyonesecret-rotememorization);thefilmandtelevisioncenterconductsimagesynthesis,replacingthebluescreenwithchartsonthecomputer;thefilmandtelevisioncenterwillcompletetheproductionoftheprogramTransmittedtoCCTV.
Ennusteiden tyypit
Jaettuna aika-alueella, eli sääennusteen keston mukaan, se voidaan jakaa:
1.Short-termforecast.Accordingtoradarandsatellitedetectiondata,thelocalstrongstormsystemwillbemonitoredandforecastedforthenext1to6hours.
2.Lyhyen aikavälin ennuste.Sääennuste seuraaville 24–48 tunnille.
3.Keskipitkän aikavälin ennuste.Seuraavan 3–15 päivän ennuste.
4.Pitkän aikavälin ennuste. Viittaa ennusteeseen 1 kuukaudesta 1 vuoteen.
5.Ultrapitkän aikavälin ennuste. Ennustejakso on 1–5 vuotta.
6.Ilmastonäkymät.Yli 10 vuotta.
Statisticalmethodsaremainlyusedtomakeforecastsbasedonthedeviationbetweentheaveragevalueofeachmonth'smeteorologicalelementsandthemulti-yearaveragevalue.Themethodofmakinglong-termforecastsusingnumericalforecastingmethodsisbeingtested,andsomeprogresshasbeenmade.Theforecastperiodof1-5yearsiscalledultra-long-termforecast,andtheforecastof5yearsormorethan10yearsiscalledclimateoutlook.
Accordingtothecoverageareatoforecasttherange,theweatherforecastcanbedividedinto:
1.Large-scaleforecast.Generallyreferstoglobalforecasts,hemisphericforecasts,continentalorcountry-wideforecasts.MainlyproducedbytheWorldMeteorologicalCenter,RegionalMeteorologicalCenterandNationalMeteorologicalCenter.
2.Keskitasoinen ennuste. Se viittaa usein maakuntien (alueiden), osavaltioiden ja alueiden ennusteisiin, jotkaprovinssin, kaupungin tai osavaltion meteorologiset asemat ja alueelliset meteorologiset asemat tuottavat.
3.Pienen mittakaavan ennuste.Esimerkiksi lääninlaajuinen ennuste, kaupunkiennuste, tekojärvenlaajuinen ennuste,jaanalentokenttä, satamaennuste jne. Nämä ennusteet ovat paikallisten meteorologisten asemien tuottamia.
ForecastService
Howtoprovidetheweatherforecasttotheuserdepartmentsandthepeopleintimeisthecentrallinkoftheforecastservice.Themostextensiveandeffectiveservicemethodsare:newspaperpublication,radiobroadcasting,televisionbroadcasting,weathertelephoneconsultation,etc.Inaddition,italsoprovidesservicestospecializeddepartmentsthroughdedicatedtelephone,telexandwrittenforms.Thespecialradioforweatherforecastisaradiothatcanbeturnedonatanytimetoreceivethecurrentweatherforecastbroadcast.Whensevereweatherisabouttohappen,thespecialweatherbroadcastingstationcanuseasignalofacertainwavelengthtomakethisradioautomaticallystartthecall.Peoplewhofallasleepcanalsobeawakenedbythesignalandhearsevereweatherwarnings,whichprovidesthepossibilitytotakepreventivemeasuresintime.
Aftertheweatherstationhasproducedtheweatherforecast,itwillannouncetheweatherforecasttothesocietythroughvariouschannels.Themainwaystodisseminateweatherforecastsaretelevision,newspapers,theInternet,mobilephonetextmessages,weathercalls,andtheInternet.ObtainingweatherforecastinformationthroughtheInternetwillbethefuturetrend.Well-knownweatherforecastwebsitesincludeChinaWeatherNetwork,CentralMeteorologicalObservatory,WeatherOnline,etc.TheCentralMeteorologicalObservatorywebsiteprovidesreal-timeweatherforecastinformationandweeklyweatherforecastinformationformajorcitiesandregionsacrossthecountry.
Yleiset ehdot
Hieno: taivaspilvi peittää alle 30 %.
Palveluinen:Taivaspilvipeite on 90 % tai enemmän.
Fog:Alargenumberoftinywaterdropletsoricecrystalsfloatintheairneartheground,andthehorizontalvisibilitydropstowithin1km,whichaffectstransportation.
Kevyt sademäärä: Päivittäinen sademäärä on alle 10 mm.
Raskaus: päivittäinen sademäärä on 25,0–49,9 mm.
Ukkoskuurot: sadekuuroja, jotka yhtäkkiä loppuvat ja putoavat salaman ja ukkonen mukana.
Hail:Thesmallhailnucleusrisesrepeatedlywiththefierceverticalmovementinthecumulonimbuscloud,condensesandmelts,andgrowsintosmalliceblockswithalternatingtransparentlayersandfalls,whichaffectscrops.
Jäätyvä sade: sadepisarat jäätyvät maahan alle 0 ℃, tunnetaan myös nimellä Yusong (jäätynyt sumupisaroista, jota kutsutaan rimeksi), joka usein katkaisee johtoja, mikä aiheuttaa liikennehäiriöitä ja vaikutuksia viestintään, virtalähteeseen, kuljetuksiin jne.
Räätä:Lämpötila maan läheisyydessä on hieman korkeampi kuin 0 ℃, märkää lumisadetta ja lumisadetta samaan aikaan.
Lightsnow:Päivittäinen lumisade (sulanut veteen) on alle 2,5 mm.
Keskilumisade: Päivittäinen lumisade (veteen sulanut) on 2,6–4,9 mm.
Ruukas lumisade:Päivittäinen lumisade (sulanut veteen) saavuttaa tai ylittää 5,0 mm.
Frost:Thewhitefrostonthegroundandthesurfaceoftheobjectwherethetemperatureislowerthan0℃iscalledfrost.Thewatervaporcontentislowandnofrostisformed.Itissaidthatblackfrostisharmfultocrops.Itiscalledfrost.
Low-pressuretroughsandhigh-pressureridges:onthefluctuatinghigh-altitudewesterlyairflow,thetroughcorrespondstothelow-pressuretrough,warmairinfrontofthetroughisactive,rainyandsnowyweather,coldairbehindthetroughiscontrolled,andwindyweatheriscool;wavecrestCorrespondingtothehighpressureridge,theskyisclear.
Coldfrontandwarmfront:Thecoldfrontisthefrontofthecoldair.Atthejunctionofthecoldandwarmairmasses,thecoldairadvancestowardthewarmair.Windyandintenseweatheronthecoldfront,strongwindsbehindthefronttocooltheweather;onthecontrary,itisawarmfront,withrainyweatheronthefront,cloudyandsunnyweatherbehindthefront,andthetemperaturerises.
GaoFeng:Expressedbythewindarrow,composedofwinddirectionrodsandwindfeathers.Thewinddirectionrodreferstothedirectionofthewindandhas8directions.Thewindplumeconsistsof3,4dashesandtrianglestoindicatethewindforceofthestrongwind,whichisperpendiculartotherightsideoftheendofthewinddirectionrod(NorthernHemisphere).
Sääennuste
Kuunnellessani sääennustetta, kuulen usein ilmauksia, kuten "tänään" ja "tänään yöllä" ja "pilvinen", "pilvinen", "aurinkoinen" jne.Meteorologiset termit.
"Tänäänpäivän aikana" tarkoittaa 12 tuntia 8:00-20:00 yöllä;"Tänä iltana" tarkoittaa 12 tuntia 20:00 - 8:00 seuraavana aamuna."Hieno" tarkoittaa, että pilvipeitteen osuus on 10-30% "tarkoittaa, että pilvipeite on 80-100%.
Meteorologisessa yksikössä on kaksi sademäärää: 12 tuntia ja 24 tuntia. 12 tunnin sademäärästandardi on: "kevyt sade" tarkoittaa 0,6-5 mm:n sademäärää; "kohtalainen"sademäärä 5,1-15 mm;"heavyra-31mm;0in.15mm;0in. Heavyrain"70.1-200mm.The24 -hourprecipitation levelstandardis:"kevyt sade"viitataan 1-10 mm;"kohtalainen"sade viittaa 10,1-25 mm;"heavyrain"sade viittaa 25,1-50 mm;"heavyrain" viittaa 50,1-100 mm:iin;"he-1 ennusteaika ei ylitä 12 tuntia, se tarkoittaa 12- tunninsadetasostandardi.Jos tänäänpäivän tai yön aikana ennustetaansateensateensateena 48 tunnin ennusteet, 72 tunnin ennusteet ja tulevaisuuden sääanalyysi.
BecausetheMeteorologicalBureauprovidesonlythreeforecastsdailytoTVstations,radiostations,andmajornewspapers:morning,noon,andevening.Itisimpossibletomaketimelyforecastsforsuddenweatherchanges.Howcanwelearnaboutsuddenweatherchangesintime?SinceSeptember2009,Chinahasopeneda121weatherhotline.Onaverage,thereisanewforecasteverytwohours,whichistimelyandaccurate,convenientandfast.Forexample,the121weatherhotlineinYangzhoucananswer60callsatthesametime,andthecallchargesareequaltoordinarylocalcalls.Mostcityweatherstations(bureaus)openofficialweathermicroblogs.
Sääennuste eläimille ja kasveille
Eläinten sääennuste
Swallows:swallowsareflyingclosetothegroundinsultryweather,itiswindyandheavyrainAsignthatiscoming.Becausetheairhumidityishighbeforeitrains,thewingsofinsectsaremoistanddonotflyhigh.Inordertocatchtheinsects,theswallowsflylowforfood.
Bee:Whencollectinghoney,itwillcomeoutearlyandreturnlate,indicatingthatthenextdaymustbesunny;ifitdoesnotleavethenestorleaveslate,itwillreturnearly,itwillberainysoon;ifWhenitrains,itcollectshoney,whichindicatesthattheskywillbeclear.
Ants:Iftheyholdwhiteseedsintheirmouths,lineupandmovetoahigherplaceinahurry,itindicatesthattherewillbecontinuousrainydaysandheavyrainfall;iftheymovetoalowerplace,Tellsus:therewillbedroughtinthefuture,andthewatersupplyhereisinsufficient.
Loach:Loachiscalled"livingbarometer".Iftheloachisirritable,churnsupanddown,andtherearemanybubblesonthewatersurface,itindicatesthatitwillrainsoonortherewillbeastrongnortherlywind;onthecontrary,iftheloachsitsquietlyonthebottomofthewater,itindicatesthattheweatherisclear.
Käärme:Käärme tuli ulos luolasta, pysyi sivuttain tiellä tai ryömi hitaasti yhteen suuntaan, mikä osoittaa, että se oli menossa sateeseen. Jos käärmeiden määrä reiästä kasvaa, se on suurempi; päinvastoin, se on pienempi.
Hämähäkki: Hämärässä, sen pinsaverkko pyydystää hyönteisiä.Tämä stotelliihmiset:Viime aikoina on aurinkoista ja taivaalla on pilviä; jos silkkinen roikkuu alas, se tarkoittaa, että sateinen päivä on tulossa.
Kilpikonna: Se on kylmäverinen eläin. Kilpikonnat kuolevat helposti haihduttamaan lämpöä ja sen ruumiinlämpö on alhaisempi kuin lämpötila. Siksi kerran kilpikonna "hiki" selässä, se tarkoittaa sadetta.
Kasvisääennuste
"Flowersknowsunnyandrainy,grassandtreesreportweather".Itwasdiscoveredthatintheplantkingdom,somememberscanpredicttheweatherlikeaweatherstation.
Themostfamous"weatherforecaster"isa100-year-oldgreengangtreeinLongdingVillage,XinchengCounty,Guangxi.Whenitissunny,itsleavesaredarkgreen,andtheweatherwillbedrybeforeitrains.,Theleavesturnred,andwhentheweatherturnsfineafterrain,theleavesreturntotheiroriginaldarkgreen.Afterresearchbyscientists,itturnsoutthatinadditiontochlorophyll,itsleavesalsocontainlutein,anthocyanin,carotene,etc.Iftheweatherisnormalandthechlorophyllmetabolismisalsonormal,theleaveswillnaturallybedarkgreen.Oncethehotandbrightweathercomes,thesynthesisofchlorophyllwillbeinhibitedandthesynthesisofanthocyaninswillbeaccelerated,sotheleaveswillturnred.
Flowersalsohave"weatherflowers".ThereisakindofwonderfulcalamusinXishuangbannainourcountry.Whenastormisabouttocome,itwillbloomwithalargenumberofbeautifulflowersandredpetalsthatdyethedeepmountainsandoldforests.Dyedredcliffs...Themysteryofthecalamuslotuspredictingwindandrainisthatbeforethestormcomes,theoutsideatmosphericpressuredrops,theweatherissultry,andtheplant'stranspirationincreases,makingitsbulbsthatstorenutrientsproducealotofhormones.,Thusbloomingalotofflowers.
Thereisalsoakindof"temperaturegrass"insouthernSweden.Itcannotonlyforecasttheweather,butalsomeasurethetemperature.Theleavesofthisgrassareoval,andtheflowersthatbloomareblue,yellow,andwhite.Peoplealsocallitpansy.Theleavesofthisplantareextremelysensitivetoairtemperature.Whenthetemperatureisabove20°C,theleavesextenddiagonallyupward;whenthetemperaturedropsto15°C,theleavesslowlymovedownwardsuntiltheyareparalleltotheground;whenthetemperaturedropsAt10°C,thebladesprotrudeobliquelydownward.Ifthetemperaturerisesandtheleavesreturntotheiroriginalstate,thelocalresidentscanknowthetemperaturelevelaccordingtothedirectioninwhichtheleavesextend.
Inthesummermorning,ifthevineheadsofthepumpkinarealltilteddown,itindicatesthatitwillrain;andintherainyweather,ifmostofthevineheadsofthepumpkinaretiltedup,itindicatesthatasunnydaywillbecoming.Coming,thisisbecausethepumpkinvinehastheinstincttobemasculineandfeminine.
Forthewaterchestnutgrowingonthesurfaceofthelakeandpond,ifthewaterchestnutplate"sinks",therewillbewindandraininthesky.Thisisbecausebeforetheonsetofrainydays,thetemperaturerisesandtheairpressuredrops,thesedimentsatthebottomofthelakesandpondsarefermented,thegeneratedbiogasescapes,blisterscontinuetoemergefromthewater,andthesludgeanddebrisfromthebottomriseandsticktotheleavesofthewaterchestnut.Up,theweightofthewaterchestnutplateincreasesandsinks.
Säänennusteen sovellus ja kehitys
Sääennusteliiketoiminta
Weatherforecastbusinessisdevelopingtowardshighertemporalandspatialresolution,perfectForecastservicesarealwaysbasedonprovidinguserswithhigheraccuracyandmoreadvancedforecastinformation.Therefore,thedevelopmentofanumericalforecastmodelsystemwithhighertemporalandspatialresolutionandlongerforecasttimelinessisalwaysthecoretaskofthedevelopmentofweatherforecasttechnology.,Statisticalpost-processingtechnologybasedonnumericalreportingmodelproducts,interpretationapplicationtechnologycombinedwiththeoccurrenceanddevelopmentofdisastrousweather,anddigitalforecasttechnologytomeetvariousneedsareinevitablerequirementsforthemoderndevelopmentofweatherservices.
Inthefuture,thedigitalforecastsystemwillfurtherdevelopgrid-basedobjectiveforecastmethods,improvethetemporalandspatialrefinementofdigitalforecastproducts,thediversificationofforecastelements,andforecastaccuracy.Onthisbasis,theestablishmentofdisastrousweatherandforecastTheall-element,multi-time-effect,andmulti-timeproductsystemofhigh-impactweatherenhancespublicandprofessionalmeteorologicalproductsupport;enhancestheintelligentandcollaborativeforecastbusinesscapabilitiesofthedigitalforecastbusinessplatform,andenhancestheautomaticweatherscaleandmesoscalesystemRecognitionfunction,improvedgraphicalinteractivecorrectionofgridelementforecasts,supportformulti-levelcollaborativehigh-temporal-spatialresolutiondigitalforecastingbusinessprocesses,andrealizenational,provincial,andcounty-levelintelligentdigitalforecastguidance,feedback,coordination,andproductionAndrelease.
Inthecentury,nationaldisasterpreventionandmitigation,protectionofsocialandeconomicdevelopment,andpeople’swell-beinghaveputforwardhigherdemandsonmeteorologicalservices,anddevelopedweatherforecastingtechnologiesandproductsfeaturing"digitalizationandrefinement".Thesystemisaninevitablerequirementtorealizethemodernizationofweatherbusiness.Italsoputsforwardhigherrequirementsforthedevelopmentofdisciplinetheoryandbreakthroughsinkeytechnologies.Standingonanewlevelofadvancementinweatherforecastingtechnology,focusingonthefrontiersofinternationalmeteorologicaltechnologydevelopment,strivingtoactivelyexploreandinnovateintherapidupdateandassimilationofmulti-sourcedataandforecastingtechnology,ensembleforecastingsystemsofdifferentscales,anddigitalforecastingtechnologies,istopromoteweatherTheonlywayfornewchangesandadvancementsinforecastingtechnology.
Sotilasmeteorologinen teknologiatyö
Newmilitaryhigh-altitudedetectionequipment,fieldweatherinstruments,militarygroundmulti-elementmeteorologicaltelemetryequipment,automaticweatherstations,etc.,forthemilitaryMeteorologicalobservationsprovidenewmeanstograduallydevelopthemilitary'smeteorologicalobservationanddetectionworkfromtraditionalmanualoperationstomodernautomatedremotesensingandremotesensing;digitalweatherradar,Dopplerweatherradarandadvancedlightningdetectionequipmenthavebeensuccessfullydevelopedandapplied,Tofurtherimprovetheabilitytomonitordangerousweatherandcatastrophicweather;theopeningofsatelliteTVweatherdatabroadcastingnetworksandpublicdatanetworks,andtheestablishmentofsatellitecommunicationnetworksinkeyareashavecausedmajorchangesinthetechnicalmeansofmeteorologicalcommunication.Thetransmissionspeed,coverage,timelinessandqualityhavebeensignificantlyimproved;theapplicationofbusinessautomationsystemssuchasweatherobservationdataprocessing,weathermapautomaticanalysisanddrawing,satellitecloudmapautomaticreceptionandprocessing,weatherdatabase,etc.,hassignificantlyenhancedthemeteorologicalinformationanalysisandprocessingcapabilities;usingtheGalaxy1.Numericalweatherforecastingbysupercomputersandadvancedlong-termweatherforecastingsystemshavesignificantlyimprovedthelevelofclimatepredictionandsignificantlyacceleratedthedigitizationprocessofweatherforecastingandweathersupport;newmobileweathersupportequipmentforfieldoperationsplaysanimportantroleinmajormilitaryexercisesTheconstructionofmilitarymeteorologicaldisciplinesandthefruitfulresultsofthetheoreticalresearchonmeteorologicalsupportforhigh-techlocalwarshaveprovidedpowerfulguidanceforthedevelopmentofmilitarymeteorologicalundertakingsandpromotedtheimprovementofmilitarymeteorologicalsupportcapabilities.
Maatalouden katastrofien ehkäiseminen ja lieventäminen
Theadvancementofinformationtechnology,theapplicationofnewtypesofmeteorologicalequipment,andtheimprovementofthetechnologyofweatherforecastersareallcontinuouslyimprovingweatherforecasting.Degreeofaccuracy.Therefore,long-termforecastsmustbeusedtoresistnaturaldisasterssuchasdrought,floods,lowtemperatureandcolddamage,andfrost.Long-termclimateforecastscanpredictthemeteorologicalchangesthatoccurwithinacertainperiodoftime,suchaswhentherewillbelowtemperature,whentherewillbedrought,whenwhentheremaybefloods,andwhenwhenthereisfrost,soyoucantaketargetedmeasuresbasedontheforecastTakeprevention.Forexample,waterconservancyprojectscanbebuiltinresponsetodroughtsandfloods,sothattheabilityoffarmlandtodrainwaterlogginganddroughtresistancecanbeenhanced.Plantingtrees,returningfarmlandtograssland,andreturningfarmlandtoforestswillchangetheregionalclimateandreducetheincidenceofsevereweather.Inaddition,long-termforecastscanprovideadvanceguidanceforagriculturalproductionplanning.Infarming,plantvarieties,plantingtime,plantingstructure,etc.areselectedaccordingtoclimaticcharacteristics.Long-termforecastscannotonlygivepeopletimetopreventdisastersinadvance,butalsomakereasonableuseofthecharacteristicsofweatherchangestoselectplantingtypesandincreaseagriculturalproductivity.
TheapplicationofthenewDopplerweatherradartechnologytoagriculturalweatherforecastshassignificantlyimprovedtheaccuracyofshort-termforecastsandshort-termforecasts.Throughthisradarmonitoringtechnology,itispossibletomonitorthechangesandmovingdirectionsofsmallandmedium-scalestrongconvectiveweatherinrealtime,ensuretheaccuracyofweatherforecasts,andreduceagriculturaldisasters.Moreover,thisweatherforecasttechnologycanalsobeappliedtootherareasoflife,suchasmunicipaltransportation,emergencycommandcenters,agriculture,wateraffairs,etc.,toformanearlywarninglinkagemechanism.Short-term,near-termweatherforecastscanbeusedtounderstandtheweatherinthearea.Ifthereisadrought,anti-aircraftartilleryandrocketscanbeusedtoartificiallyaffecttheweatherforartificialprecipitation.Ifhailweatheroccurs,humaninterventioncanalsobeusedtopreventhail.Atpresent,animportantmeasureforeffectivedisasterpreventionandmitigationinagriculturalproductionisartificialinfluence,andshort-termandnear-termweatherforecastwarningsprovideitwithmeteorologicalinformation,combinedwithreal-timeradarmonitoring,andartificialinfluencetochangeregionalweathertoachievedroughtresistance,hailprevention,andPurposessuchasincreasingrainfall.Forexample,in2010,LiuzhouCitysufferedfromseverelylowrainfall,allcropsinthecitysufferedfromdrought,reservoirswereinsufficientlystored,andtheforestfirepreventionsituationwasalsosevere.Inresponsetoseveredrought,LiuzhouCityimplementedartificialweatherinfluencingoperations,comparedwithnon-operatingareas.Increasedby20mm,theeffectofincreasingrainfallreached20%,completelyeliminatingtheagriculturaldrought.Practicehasprovedthattheimpactofmanualoperationsonthebasisofshort-termandnear-termweatherforecastscanreduceoreliminateagriculturaldisasters.