Home Tekniikka 10 Gigabit Ethernet

10 Gigabit Ethernet



Introduction

Inthese20years,Ethernethasdevelopedfromtheoriginal10Base510Mthickcablebusto10Base210Mthincable,followedbyashortretreat:1Base51MEthernet,AndthentheEthernettechnologydevelopedintothefamiliarstar-shapedtwistedpair10BaseT.Withtheincreaseinbandwidthrequirementsandtheenhancementofdevicecapabilities,fastEthernethasemerged:100BaseTXforCategory5cabletransmission,100BaseT4forCategory3cabletransmission,and100BaseFXforopticalfibertransmission.Withthefurtherincreaseinbandwidth,GigabitEthernetinterfacesareonthescene:includingshort-wavelengthopticaltransmission1000Base-SX,long-wavelengthopticaltransmission1000Base-LX,andCategory5linetransmission1000BaseT.OnJuly18,2002,IEEEpassed802.3ae:10Gbit/sEthernet,alsoknownas10GigabitEthernet.

10GigabitEthernetdoesnotsimplyincreasethespeedofGigabitEthernetby10times.Therearemanytechnicalproblemstobesolvedhere.

InEthernettechnology,100BaseTisamilestone,establishingthedominanceofEthernettechnologyonthedesktop.GigabitEthernetandthesubsequent10GigabitEthernetstandardsaretwomoreimportantstandards.Throughthesetwostandards,EthernettechnologyextendsfromdesktopLANtechnologytocampusnetworksandtheconvergenceandbackboneofmetropolitanareanetworks.

Ethernetin kehitys 10 Mb:sta 10 Gt:iin/vahvisti Ethernetin:

1.Skaalautuva (alkaen 10Mb/to10Gb/s).

2. Joustava (multimedia, täysi/halfduplex, jakaminen/vaihtaminen).

3.Helppo asentaa.

4.Hyvä toimintakyky.

Foundingbackground

Ethernetisdominantinlocalareanetworks.Butforalongperiodoftime,peoplegenerallybelievedthatEthernetcouldnotbeusedinmetropolitanareanetworks,especiallytheconvergencelayerandbackbonelayer.ThemainreasonisthatthebandwidthofEthernetusedasthebackboneofthemetropolitanareanetworkistoolow(intheeraof10Mand100MfastEthernet),andthetransmissiondistanceistooshort.Atthattime,themostpromisingmetropolitanareanetworktechnologieswereFDDIandDQDB.Inthefollowingyears,ATMtechnologyhasbecomeahotspot.AlmosteveryonebelievesthatATMwillbecometheonlytechnologythatunifieslocalareanetworks,metropolitanareanetworks,andwideareanetworks.However,duetovariousreasons,onlyATMtechnologyamongtheabove-mentionedthreetechnologiesinChinahasbecomeanalternativesolutionfortheconvergencelayerandbackbonelayerofthemetropolitanareanetwork.

ThemostcommonEthernetis10MEthernetand100MEthernet(FastEthernet).100MFastEthernetisobviouslynotenoughasametropolitanareabackbonenetwork.EvenifmultiplefastEthernetlinksareusedincombination,theystillhavemorethanenoughcapacityformultimediaservices.WiththestandardizationofGigabitEthernetanditswideapplicationinproductionpractice,Ethernettechnologyhasgraduallyextendedtotheconvergencelayerofthemetropolitanareanetwork.GigabitEthernetisusuallyusedtoconvergecommunityuserstometropolitanPOPpoints,ortoconnectconvergencelayerequipmenttothebackbonelayer.However,inthecurrentenvironmentof10MEthernettotheuser,GigabitEthernetlinkisalsoreluctantasanaggregation,anditisbeyondreachasabackbone.AlthoughEthernetmulti-linkaggregationtechnologyhasbeenstandardizedandmulti-vendorinteroperabilityisjustaroundthecorner,multiplegigabitlinkscanbebundledandused.However,consideringfiberresourcesandwavelengthresources,linkbundlingisgenerallyonlyusedinPOPpointsorshort-distanceapplicationenvironments.

TransmissiondistanceusedtobeamajorobstaclethatEthernetcannotbeusedasalinktechnologyatthebackbonelayerofthemetropolitanareadatanetwork.Whetheritis10M,100MorGigabitEthernet,thetransmissiondistanceofCategory5linesis100mduetothesignal-to-noiseratio,collisiondetection,andavailablebandwidth.Whenusingopticalfibertransmission,thedistancelimitisrestrictedbythemaster-slavesynchronizationmechanismusedbyEthernet.802.3stipulatesthatthe1000Base-SXinterfaceusesa62.5μmcoremultimodefiberwithalongesttransmissiondistanceof275manda50μmcoremultimodefiberwithalongesttransmissiondistanceof550m;1000Base-LXinterfaceusesa62.5μmcoremultimodefiberwiththelongesttransmissiondistance.Thetransmissiondistanceis550m,thelongesttransmissiondistanceis550mwhenusingamultimodefiberwithacoreof50μm,andthelongesttransmissiondistanceis5000mwhenusingasingle-modefiberwithacoreof10μm.Thelongesttransmissiondistanceof5kmGigabitEthernetlinkisfarfromenoughinthemetropolitanarea.AlthoughtheGigabitinterfaceimplementationbasedonthemanufacturercanreachatransmissiondistanceof80km,andsomemanufacturershavecompletedinteroperabilitytests,itisanon-standardimplementationafterallandcannotguaranteetheinteroperabilityofthistypeofinterfacefromallmanufacturers.

Tosumup,themainreasonwhyEthernettechnologyisnotsuitableforuseinthebackbone/aggregationlayerofthemetropolitanareanetworkisbandwidthandtransmissiondistance.Withtheemergenceof10GigabitEthernettechnology,theabovetwoproblemshavebasicallybeenresolved.

Technicalintroduction

EthernetusestheCSMA/CDmechanism,thatis,carriersensemultipleaccesswithcollisiondetection.GigabitEthernetinterfacesarebasicallyusedinpoint-to-pointlines,andnolongersharebandwidth.Collisiondetection,carriersenseandmultipleaccessarenolongerimportant.ThebiggestsimilaritybetweenGigabitEthernetandtraditionallow-speedEthernetisthatitusesthesameEthernetframestructure.10GigabitEthernettechnologyissimilartoGigabitEthernet,butstillretainstheEthernetframestructure.Provide10Gbit/stransmissionspeedthroughdifferentencodingmethodsorwavelengthdivisionmultiplexing.Soinitsessence,10GEthernetisstillatypeofEthernet.

10GEthernet ohitettiin IEEE:ssä heinäkuussa 2002.10GEthernet sisältää 10 GBASE-X, 10 GBASE-R, 10 GBASE-W ja 10 GBASE-T-pohjainen kuparikaapeli (hyväksytty vuonna 2006). nm-aallonpituus, joka on noin 25 nmin välein, jokainen lähetin/vastaanotinpari toimii nopeudella 3,125 Gbit/s (tietovirtanopeus 2,5 Gbit/s). /66Benkoodaus (ei 8B/10Gigabit-Ethernetissä käytössä).Tietovirta on 10,000 Gbit/s, ja tuloksena kellonopeus on 10,3 Gbit/s.10 GBASE-Wisawideareanverkkoliitäntä, yhteensopiva SONETOC-192:n kanssa, sen kello on 9,953 dabit/s.

10G-sarjafyysinen mediakerros

Optinen kuitu10 Gigabit Ethernet-tiedot paikallisia verkkoja varten ovat: 10 GBase-SR, 10 GBase-LR ja 10 GBase-ER.

1,10GBase-SR

"SR" in10GBase-SR on lyhenne sanoista "lyhyt väli",joka tarkoittaa, että sitä käytetään vain lyhyen matkan yhteyksiin. Tämä eritelmä tukee lyhytaalto (850 nm aallonpituus) monimuotokuitu (MMF) koodausmenetelmällä64B/66B.

2,10 Gt:n perus-LR

10GBase-LR:n "LR" on lyhenne sanoista "Long Range", mikä tarkoittaa, että sitä käytetään pääasiassa pitkän matkan yhteyksiin. Tekniset tiedot tukevat pitkän aallon (1310 nm) yksimuotokuitua (SMF) koodausmenetelmällä64B/66B.

4,10GBase-ER

"ER" in10GBase-ERon"ExtendedRange"-lyhenne, mikä tarkoittaa, että yhteysetäisyys voi olla erittäin pitkä.Tämä spesifikaatio tukee erittäin pitkää aaltoa (1550 nm)yksimuotoista kuitua (SMF) ja koodausmenetelmää64B/66B:n 2-mittaisen lähetyksen etäisyydelle0.

PMDsulayerfunction

ThefunctionofthePMDsublayeristosupporttheexchangeofserializedsymbolcodebitsbetweenthePMAsublayerandthemedium.ThePMDsublayerconvertstheseelectricalsignalsintoaformsuitablefortransmissiononaspecificmedium.PMDisthelowestsublayerofthephysicallayer.Thestandardspecifiesthatthephysicallayerisresponsibleforsendingandreceivingsignalsfromthemedium.

PMAsulayerfunction

ThePMAsublayerprovidesaserializedserviceinterfacebetweenthePCSandPMDlayers.TheconnectionwiththePCSsublayeriscalledthePMAserviceinterface.Inaddition,thePMAsublayeralsoseparatesthesymboltimingclockusedforcorrectsymbolalignment(delimitation)ofthereceiveddatafromthereceivedbitstream.

WISssulayerfunction

TheWISsublayerisanoptionalphysicalsublayer,whichcanbeusedbetweenPMAandPCStoproduceadaptationsdefinedbyANSISONETSTS-192ctransmissionformatorITUdefinesSDHVC-4-64ccontainerrateEthernetdatastream.Thisratedatastreamcanbedirectlymappedtothetransportlayerwithouthigh-levelprocessing.

PCS-alikerroksen toiminto

ThePCSsublayerislocatedbetweenthecoordinationsublayer(viaGMII)andthephysicalmediumaccesslayer(PMA)sublayer.ThePCSsublayercompletesthemappingofthewell-definedEthernetMACfunctiontotheexistingcodingandphysicallayersignalsystemfunctions.TheinterfacebetweenthePCSsublayerandtheupperlayerRS/MACisprovidedbyXGMII,andthelowerlayerPMAinterfaceusesthePMAserviceinterface.

RS(coordinationssublayer)jaXGMII

ThefunctionofthecoordinationsublayeristomaptheXGMIIchanneldataandrelatedcontrolsignalstotheoriginalPLSserviceinterfaceDefinethe(MAC/PLS)interface.TheXGMIIinterfaceprovidesalogicalinterfacebetweenthe10Gbit/sMACandthephysicallayer.XGMIIandthecoordinationsublayerenableMACtoconnecttodifferenttypesofphysicalmedia.

Because10GEthernetisessentiallyahigh-speedEthernet,inordertobecompatiblewithtraditionalEthernet,theframeformatoftraditionalEthernetmustbeusedtocarryservices.Inordertoachieveahighrateof10Gbit/s,theOC-192cframeformatcanbeusedfortransmission.ThisneedstorealizethemappingfunctionfromEthernetframetoOC-192cframeformatinthephysicalsublayer.Atthesametime,becausetheoriginaldesignofEthernetisforlocalareanetwork,thenetworkmanagementfunctionisweak,thetransmissiondistanceisshort,anditsphysicallinedoesnothaveanyprotectivemeasures.WhenEthernetisusedasawideareanetworkforlong-distance,high-speedtransmission,itwillinevitablycausegreaterjitterinthefrequencyandphaseofthelinesignal,andthetransmissionofEthernetisasynchronous,anditisdifficulttoachievesignalsynchronizationatthereceivingend.Therefore,iftheEthernetframeistobetransmittedinthewideareanetwork,theformatoftheEthernetframeneedstobemodified.

Ethernetgenerallyusesaspecial10B(Byte)codeinthephysicallayertoachieveframedelimitation.WhentheMAClayerhasdatatosend,thePCSsublayerencodesthedatain8B/10B.Whenitfindstheframeheaderandframeend,itautomaticallyaddsthespecialcodegroupSFD(startofframedelimiter)andEFD(endofframe)Delimiter);whenthePCSsublayerreceives10Bcodeddatafromthebottomlayer,itcaneasilyfindthestartandendoftheframeaccordingtoSFDandEFDtocompletetheframedelimitation.However,theGigabitEthernetframedelimitationcarriedinSDHisdifferentfromthestandardGigabitEthernetframedelimitation,becausethemultiplexeddatahasbeenrestoredtoan8Bcodegroup,withSFDandEFDremoved.Ifonlythepreambleandthestartofframedelimiter(SFD)oftheGigabitEthernetareusedforframedelimitation,becausetheprobabilityofthesamecodegroupasthepreambleandthestartofframedelimiterintheinformationdataishigher,useSuchaframedelimitationstrategymaycausethereceivingendtobeunabletoperformcorrectEthernetframedelimitationallthetime.Inordertoavoidtheabove-mentionedsituation,10GEthernetadoptstheHECstrategy.

TheIEEE802.3HSSGgroupproposedtomodifytheGigabitEthernetframeformat,addingthelengthfieldandtheHECfieldtotheEthernetframe.Inordertofindthepositionofthenextframeconvenientlyduringtheframingprocess,andsincethemaximumframelengthis1518bytes,atleast11bits(=2048)arerequired,sotwobytesareusedtoreplacethepreambleintheprocessofmultiplexingMACframesThefirsttwobytesareusedasthelengthfield,andthentheCRC-16checkisperformedonthese8bytes,andthelasttwobytesobtainedareinsertedaftertheSFDastheHEC.

The10GWANphysicallayerdoesnotsimplyuseOC-192ctocarryEthernetMACframes.Althoughtheblockframestructure,pointer,mapping,andlayeredoverheadofOC-192careusedforreference,alotofsimplificationshavebeenmadeonthebasisofSDHframestructure,whichmakesthemodifiedEthernetinsensitivetojitterandrequiresclocks.nottall.Specificperformance:Manyoverheadbytesarereduced,onlyframepositioningbytesA1andA2,segmentlayererrormonitoringB1,tracebyteJ0,synchronizationstatusbyteS1,protectionswitchingbytesK1andK2,andsparebytesareusedZ0,fill00000000forundefinedorunusedbytes.Itreducesalotofunnecessaryoverhead,simplifiestheSDHframestructure,andenhancesthenetworkmanagementandmaintenanceofthephysicallayercomparedwithGigabitEthernet,andcanrealizeprotectionswitchingonthephysicalline.Secondly,cumbersomesynchronousmultiplexingisavoided.Thesignalisnotmultiplexedfromalowratetoahighratestream,butdirectlymappedtotheOC-192cpayload.

Therateofthephysicallayerof10GEthernetLANand10GEthernetWAN(usingOC-192c)isdifferent.Thedatarateof10GEthernetLANis10Gbit/s,whilethedatarateof10GEthernetWANis9.58464Gbit/s(SDHOC-192cistheunencodedrateofthePCSlayer),butthephysicallayersofthetworatesshareaMAClayer,andtheworkingrateoftheMAClayeris10Gbit/s.Whatkindofadjustmentstrategyisadoptedtoreducethe10Gbit/stransmissionrateofthe10GMIIinterfacetomatchthephysicallayertransmissionrateof9.58464Gbit/sisaproblemthatthe10GEthernetWANneedstosolve.TherearethreeadjustmentstrategiesfortheOC-192cthatadaptsthe10Gbit/srateto9.58464Gbit/s:

SendtheHOLDsignalattheGMIIinterface,andtheMAClayerstopssendinginoneclockcycle;

Käyttämällä "Varattu"-toimintoa,fyysiset kerrokset lähettävät "Varattu"MAC-tasolleIPG:n aikana. Vastaanotettuaan sen, MAClayers keskeyttää tietojen lähettämisen. Fyysiset kerrokset lähettävät "Normalidle"MAC-tasolleIPG:n aikana,javastaanotettuaan sen;

AdoptstheIPGextensionmechanism:MACframesaretransmittedoneframeatatime,dynamicallybasedontheaveragedatarateAdjusttheIPGinterval.

Tekninen luokitus

Gigabitin Ethernet-standardeja ja teknisiä tietoja on useita. Standardien välillä on IEEE 802.3aein2002, IEEE 802.3akin2004 ja IEEEin2006.802.3an, IEEEin2006.802.3an, EE 2003a20a. 007.Spesifikaatioiden suhteen on olemassa yli 10,jotka voidaan jakaa kolmeen luokkaan:yksi on LAN10GigabitEthernet-spesifikaatiooptiseen kuituun,nämä on LAN10GigabitEthernet-spesifikaatio, joka perustuu kierrettyyn pariin (tai kupariin perustuvaanverkkoon. .

TechnologyOutlook

Atthebeginningofthedesignof10GigabitEthernet,therequirementsofthemetrobackbonenetworkwereconsidered.Firstofall,thebandwidthof10Gissufficienttomeetthebandwidthrequirementsofthemetrobackbonenetworkatthisstageandforaperiodoftimeinthefuture(thebackbonebandwidthofmostmetrobackbonenetworksatthisstagedoesnotexceed2.5G).Secondly,themaximumtransmissiondistanceof10GigabitEthernetcanreach40kilometers,anditcanbeusedwith10Gtransmissionchannels,whichisenoughtomeetthecoverageofmosturbanmetropolitanareanetworks.Using10GigabitEthernetasthebackboneofthemetropolitanareanetworkcanomitthePOSorATMlinkofthebackbonenetworkequipment.Firstofall,itcansavecosts:thepriceoftheEthernetportismuchlowerthanthecorrespondingPOSportorATMport.Secondly,itispossibletouseEthernetframesend-to-end:ontheonehand,theVLANinformationandpriorityinformationofthelinklayercanbeusedend-to-end,andontheotherhand,multiplelinklayerencapsulationanddecapsulationonthedatadevicecanbeomitted.Possiblefragmentationofdatapacketstosimplifynetworkequipment.Theuseof10GigabitEthernetlinksatthebackbonelayerofthemetropolitanareanetworkcanimprovethecost-effectivenessofthenetworkandsimplifythenetwork.

Wecanclearlyseethat10GEthernetcanbeappliedtocampusnetworks,metropolitanareanetworks,andcorporatenetworks.However,becausethecurrentbroadbandservicesarenotwidelydeveloped,peopledonothaveanurgentneedforthebandwidthofasingle-port10Gbackbonenetwork.Therefore,10GEthernettechnologyisnotasgoodasotheralternativelinklayertechnologies(suchas2.5GPOS,bundledGigabitEthernet).Thereisnoobviousadvantage.CiscoandJUNIPERhaveintroduced10GEthernetinterfaces(implementedaccordingtothe802.3aedraft),buttheyhavealmostnoapplicationsinChina.Theproblemwiththemetropolitanareanetworkisnotthelackofbandwidth,buttheKillerApplication,whichconsumesalargeamountofbandwidth.Howtobuildthemetropolitanareanetworkintoamanageable,operableandprofitablenetwork.Sotheapplicationof10GEthernettechnologywilldependonthedevelopmentofbroadbandservices.Onlytheextensivedevelopmentofbroadbandservices,suchasvideomulticast,high-definitionTVandreal-timegames,canpromotethewidespreadapplicationof10GEthernettechnologyandpromotethehealthyandorderlydevelopmentofthenetwork.

Technicalfeatures

10GigabitEthernettechnologyprovidesricherbandwidthandprocessingcapabilities,whichcaneffectivelysaveusers’investmentinlinksandmaintainEthernetcompatibility.,Simpletouseandeasytoupgrade.However,wealsoseethatbecause10GigabitEthernetisstillintheearlystagesofdevelopment,therearestillsomeproblemsandshortcomings:First,intermsofprice,thepriceofa10GEportisabout100timesthatofaGEport,especiallywhenthebandwidthisnotavailable.Inthecaseoffullutilization,itwillcauseagreatwasteofinvestment;secondly,10GigabitEthernetinheritstheusualweakQoScharacteristicsofEthernet,andtheproblemofhowtoguaranteethedifferentiatedservicebearerremainsunsolved.FeaturessuchasRPR,MPLS,etc.Thesupportofthesystemisstillimmature;furthermore,10GErequiresequipmenttohavepowerfulprocessingcapabilities,andthe10GEportsintroducedbysomemanufacturersintheindustrycannotachievetruewire-speedprocessing,andthebandwidthadvantageisgreatlyreduced.

Inviewoftheabove-mentionedproblemsandthecurrentsituationwherethedemandfornetworkbandwidthisnoturgent,itisrecommendedthatthenetworkconstructionfocusonbusinessandcostperformance,andthenetworkcorestilladopts2.5GPOSinterfaceorGETrunkmode.When10GigabitEthernetisintermsoftechnologyandcostAftermajorprogresshasbeenmade,itwillbesmoothlyupgradedto10G.

Technicaladvantages

Oneoftheadvantagesof10GigabitEthernetisthatitcanusethesameformfactorinterfaceasGigabitEthernettoobtaintentimesthebandwidth.Thisappliestoswitchportsandhostadapterports.Forexample,onahostserver,ifyouneedeightGigabitEthernetnetworkcardinterfaces,youcanusetwofour-portnetworkcards,fourdual-portnetworkcards,oreightsingle-portnetworkcards.Thiscantakeuptwo,four,oreightserverI/Oslotsandresultineightcablescomingoutoftheserver.Thiscanbedoneinsomecases,butnotallservershavesomanyslots.SomeserverI/Oslotsneedtobeusedforotherpurposes,suchasRAIDcontrollers,FibreChannelhostbusadapters(HBAcards),PCIExpress(PCIe)SSDandsoon.Ifyouusea10GigabitEthernetport,withadual-port10GigabitEthernetcard,oneportcanprovideuptoeightGigabitEthernetinterfaces,whiletheremainingoneisusedforfailoverorothermanagementpurposes.ThiswillonlyoccupyoneI/Oslot,freeuptheI/Oslot,andreducepowerconsumptionatthesametime.Andnomorethantwocablesareneeded.Inaddition,thesamedual-port10GigabitEthernetcardcanbeinstalledonasmallerserver,suchasa1Userverwithonlytwoslots,andstillprovidesufficientnetworkbandwidth.

Developmenthistory

Amongdomesticnetworkmanufacturers,HuaweihastakentheleadinlaunchingtheQuidwayS8500(8505/8512),ahigh-endrouterandswitchsupporting10Gigabit,whichispositionedasacarrier-classoperatingcorenetworkThecoreoftheconvergencelayer,campusnetwork,andenterprisenetwork.QuidwayS8510Gigabitmulti-layercoreswitchhasthecharacteristicsoflargecapacity,richserviceinterfacefeatures,andcompleteprotocolsupport.Thebackplanecapacityis1.2T,theswitchingcapacityis480Gbps,andtheEthernetinterfaceprovidesamaximumof1210GigabitEthernetinterfaces.VPNsupportabilityandperfectQoSability.TheQuidwayNetEngine5000series10Gigabitcorerouterslaunchedatthesametimearehigh-endnetworkproductsforcarrier-classoperatingcorenetworks.Theyadoptathree-dimensionalswitchingnetworkdistributedarchitecture.Eachinterfacemodulehasitsowndistributedswitchingnetwork,whichcanbeeasilystackedandexpanded.Providesamaximumof560interfacemodules,thewholemachineprovides11.2Tbpsswitchingcapacity,themaximumportcapacityis5.6T,supports10GPOS,10GELAN,10GEWANinterfaceIP/MPLSwire-speedforwarding,andsupportssmoothexpansiontohigher-speedinterfaces.TheQuidwayNetEngine50Gigabitcorerouteradoptsathree-dimensionalarchitecture,whichhasadvantagesinscalability,loadbalancing,multi-pathbackup,andnon-blocking.Italsohasincrementalscalabilityandcanincreaseswitchingcapacityasneededwithouthavingtodoitallatonce.Thehighgroundisequippedwithacentralizedswitchingnetworktomeetthecharacteristicsandneedsoffuturecorenetworkdevelopment.

Inaddition,Huawei'sfifth-generationhigh-endcorerouterQuidwayNetEngine80/40alsohastheabilitytosmoothlyupgradeto10G.ThelaunchoftheQuidwayseriesof10Gigabitroutersandswitchesmarksthatthedesigntechnologyofmycountry'slarge-capacitycoreroutersandEthernetswitcheshasenteredtheinternationaladvancedlevel.Thisisnotonlyamajorbreakthroughinthedevelopmentofmycountry'scorenetworkcommunicationtechnology,butalsomycountry'sdatacommunicationindustry.Amajorbreakthroughtowardsinternationalization,andwillprovideastrongerdevelopmentimpetusforthefurtherdevelopmentofmycountry'sinformatization.

This article is from the network, does not represent the position of this station. Please indicate the origin of reprint
TOP