Domov Technika Gigabit Ethernet

Gigabit Ethernet



Introduction

DevelopmentStatus

GigabitEthernetisatechnologybasedonbasicEthernetstandards.GigabitEthernetandthewidelyusedEthernetarefullycompatiblewithFastEthernet,anduseallthetechnicalspecificationsstipulatedbytheoriginalEthernetstandard,includingCSMA/CDprotocol,Ethernetframe,fullduplex,flowcontrolandIEEE802.3Managementobjectsdefinedinthestandard.AsanintegralpartofEthernet,GigabitEthernetalsosupportstrafficmanagementtechnology,whichguaranteesthequalityofserviceonEthernet.ThesetechnologiesincludeIEEE802.1Player2priority,layer3priorityQoScodingbits,specialServiceandResourceReservationProtocol(RSVP).

GigabitEthernetalsoutilizesIEEE802.1QVLANsupport,fourth-levelfiltering,andGigabitthird-levelswitching.GigabitEthernetwasoriginallydesignedasaswitchingtechnology,usingopticalfiberastheuplinkforconnectionsbetweenbuildings.Later,intheconnectionofserversandbackbonenetworks,GigabitEthernethasbeenwidelyused.DuetotheintroductionoftheIEEE802.3abstandard(GigabitEthernetstandardusingcategory5andaboveunshieldedtwistedpair),GigabitEthernetcanbeused.Applicabletoanylarge,mediumandsmallenterprisesandinstitutions.

GigabitEthernethasdevelopedintoamainstreamnetworktechnology.Largeenterprisesaslargeastensofthousandsofpeople,smallandmedium-sizedenterprisesassmallasdozensofpeople,willuseGigabitEthernettechnologyasthepreferredhigh-speednetworktechnologywhenbuildingcorporateLANs.GigabitEthernettechnologyisevenreplacingATMtechnology,becomingthemainforceintheconstructionofmetropolitanareanetworks.

Features

1.GigabitEthernetprovidesaperfectmigrationpath,fullyprotectingtheinvestmentintheexistingnetworkinfrastructure.GigabitEthernetwillretainIEEE802.3andEthernetframeformatsand802.3managedobjectspecifications,sothatenterprisescanupgradetogigabitperformancewhileretainingexistingcables,operatingsystems,protocols,anddesktopapplicationsProgramandnetworkmanagementstrategiesandtools;

2.ComparedwiththeoriginalbackbonenetworksolutionssuchasFastEthernet,FDDI,andATM,GigabitEthernetprovidesanoptimalpath.Atleastfornow,itisareliableandeconomicalwaytoimprovethebackboneconnectionbetweentheswitchandtheswitchandtheconnectionbetweentheswitchandtheserver.Networkdesignerscanbuildahigh-speedinfrastructurethateffectivelyuseshigh-speed,mission-criticalapplicationsandfilebackups.NetworkmanagerswillprovideuserswithfasteraccesstotheInternet,Intranet,MetropolitanAreaNetworkandWideAreaNetwork.

3.TheIEEE802.3workinggroupestablishedthe802.3zand802.3abGigabitEthernetworkinggroups,whosetaskistodevelopGigabitEthernetstandardsthatmeetdifferentneeds.Thisstandardsupportsfull-duplexandhalf-duplex1000Mbps,andthecorrespondingoperationadoptsIEEE802.3EthernetframeformatandCSMA/CDmediaaccesscontrolmethod.GigabitEthernetisalsobackwardcompatiblewith10BaseTand100BaseT.Inaddition,theIEEEstandardwillsupportmultimodefiberswithamaximumdistanceof550meters,single-modefiberswithamaximumdistanceof70kilometers,andcoppercableswithamaximumdistanceof100meters.GigabitEthernetfillsinthedeficienciesofthe802.3Ethernet/FastEthernetstandard.

Construction

TheGigabitEthernetnetworkiscomposedofGigabitswitches,Gigabitnetworkcards,andintegratedwiringsystems.Thegigabitswitchformsthebackboneofthenetwork.Thegigabitnetworkcardisinsertedintotheserverandconnectedtotheswitchthroughawiringsystem.Therecanalsobemany100Mswitchesunderthegigabitswitch,andthe100Mswitchisconnectedtotheworkstation.Thisistheso-called"100MTothedesktop".Insomeprofessionalgraphicsproductionandvideo-on-demandapplications,"GigabittoDesktop"mayalsobeused,andaGigabitswitchisusedtoconnecttoaworkstationwithaGigabitnetworkcard,whichmeetsthedemandforhighbandwidthunderspecialapplications.

Beforebuildinganetwork,whethertouseGigabitor100M,wemuststartfromtheactualsituation,startfromtheapplication,andconsiderwhatfunctionsthenetworkshouldhave.Differentapplicationshavedifferentrequirements,andthereisalmostnonetworkwithasingleservice.However,amongthevariousbusinesses,theproductivebusinessisdefinitelythehighestpriority.Ifvoiceistransmittedoverthenetwork,thenvoiceservicesalsoneedtobeprioritized.Ifthedemandforbusinesspriorityishigh,thenetworkmusthaveQoSguarantees.Suchanetworkmustbeintelligent.Theswitchportcanidentifywhattypesofservicesarepassing,andthenqueueupdifferentservices,andallocatedifferentbandwidthsfordifferentservices,soastoensuretheoperationofkeyservices.Thedataserviceitselfisintelligent,anditcanbetransmittednomatterhowmuchbandwidthitis,justthelengthoftime,butthevoiceorvideoisnotthesame.Ifthebandwidthissmall,itwillbedifficulttohearimmediately,ortheimagewillbejittery.notallowed.SoQoSisveryimportant.Forapuredatanetwork,thedemandforQoSisverylow.Whenplanningthenetwork,youmustfirstunderstandwhichfunctionsarenecessaryandwhichcannotbeconsidered.Forexample,multicastingisoneofthemoreimportantfeatures.Ifimagesneedtobetransmittedonthenetwork,andthenetworkdoesnothavethecharacteristicsofmulticasting,thebandwidthwasteofthenetworkwillbeveryserious,orevenimpossibletoachieve.

International Standard

V lednu 1997 byl schválen první návrh IEEE802.3z;

V červnu 1997 byl schválen návrh V3.1. Konečné technické podrobnosti jsou formulovány zde;

V červnu 1998 byla norma IEEE802.3z formálně schválena;

V červnu 1999 byl formálně schválen nestandardní standard IEEE 802.3 (tj. 1000Base-T), můžete použít kroucené kabely pro gigabitový Ethernet.

TheGigabitEthernetstandardmainlytargetsthreetypesoftransmissionmedia:single-modefiber;long-wavelaseronmulti-modefiber(called1000BaseLX),short-wavelaseronmulti-modefiber(called1000BaseSX));1000BaseCXmedium,whichcanbetransmittedonabalancedshielded150ohmcoppercable.The1000BaseTstandardsimulatedbytheIEEE802.3zcommitteeallowsthetransmissiondistanceofGigabitEthernetonCategory5,Super5,andCategory6UTPtwisted-pairlinestobeextendedto100meters,sothatmostofthewiringinthebuildingadoptsCategory5UTPtwistedpaircableguaranteestheuser'spreviousinvestmentinEthernetandFastEthernet.Fornetworkadministrators,thereisnoneedtoacceptnewtraining.WiththeknowledgeofEthernetnetworks,theycanmanageandmaintainGigabitEthernet.

ThestandardizationofGigabitEthernetincludesthreemainmodules:encoding/decoding,transceiver,andnetworkmedia.Differenttransceiverscorrespondtodifferentnetworkmediatypes.When1000BASE-LXisbasedonthe1300nmsingle-modeopticalcablestandard,ituses8B/10Bencodinganddecoding,andthemaximumtransmissiondistanceis5000meters.1000BASE-SXisbasedon780nmFibreChanneloptics,using8B/10Bencodinganddecodingmethods,using50micronor62.5micronmultimodeopticalcables,andthemaximumtransmissiondistanceis300metersto500meters.TheSCtypeopticalfiberconnectorusedtoconnecttheopticalfiberisofthesamemodelastheconnectorusedinFastEthernet100BASEFX.1000BASE-CXisastandardbasedoncoppercables,using8B/10Bencodinganddecodingmethods,withamaximumtransmissiondistanceof25meters.1000BASE-Tisbasedonunshieldedtwistedpairtransmissionmedium,using1000BASE-TcopperphysicallayerCopperPHYencodinganddecodingmethod,thetransmissiondistanceis100meters.1000BASE-Tusesall4twistedpairsintransmissionandworksinfullduplexmode.ThisdesignusesPAM-5(5-levelpulseamplificationmodulation)encodingtotransmit250Mbpsoneachpair.Two-waytransmissionrequiresthatallfourwire-pairtransceiverportsmustuseahybridmagneticfieldcircuit.Becauseaperfecthybridmagneticfieldcircuitcannotbeprovided,itisimpossibletocompletelyisolatethetransmittingandreceivingcircuits.Anysendingandreceivinglineswillechotheequipment.Therefore,toachievetherequirederrorrate(BER),theechomustbecanceled.1000BASE-Tcannotfilterthefrequencybandsabove125MHz,buttheuseofscramblingtechnologyandtrelliscodingcanfilterthefrequencybandsafter80MHz.InordertosolvethelimitationofCategory5linesduetonear-endcrosstalkinsuchahighfrequencyrange,appropriatesolutionsshouldbeadoptedtooffsetthecrosstalk.

TheoriginalGigabitEthernetusedhigh-speed780nmfiberchannelopticalcomponentstotransmitsignalsonopticalfibers,andused8B/10Bencodinganddecodingmethodstoachieveserializationandrestorationofopticalsignals.ThedataoperatingrateofFibreChanneltechnologyis1.063Gbps,whichwillbeincreasedto1.250Gbpsinthefuture,enablingthedataratetoreachacomplete1000Mbps.Forlongerconnectiondistances,1300nmopticalcomponentswillbeused.Inordertoadapttothedevelopmentofsilicontechnologyanddigitalsignalprocessingtechnology,amedium-independentlogicalinterfaceshouldbeestablishedbetweentheMAClayerandthePHYlayer,sothatGigabitEthernetcanworkinanunshieldedtwistedpaircablesystem.Thislogicalinterfacewillbeapplicabletotheencodingmethodofunshieldedtwistedpaircablesystemsandisindependentoftheencodingmethodoffiberchannel.ThefollowingfigureillustratesthecompositionofGigabitEthernet.

GigabitEthernet

Therearenotmanyconditionsforupgrading10Mand100MnetworkstoGigabit.Themostimportantthingistheintegratedwiringconditions.GigabitEthernetreferstothebandwidthofthenetworkbackbone,andthebackbonecablingsystemmustmeettherequirementsofGigabitEthernet.Iftheoriginalnetworkcoversmultiplebuildingsseparatedbyseveralhundredmeterstoseveralkilometers,theoriginalbackbonewiringgenerallyusesmulti-modeorsingle-modefiber,whichcanmeettherequirementsofagigabitbackbone,andthereisnoneedtore-laythefiber.Whenthedistancebetweenbuildingsislessthan550meters,generallylayingrelativelyinexpensivemulti-modeopticalfibercanmeettheneedsofGigabitEthernet.

Iftheoriginalnetworkonlycoversonebuilding,andthedistancebetweenthefurthestnetworknodeandthenetworkcenterisnomorethan100meters,theoriginalCategory5orCategory5cablingsystemcanbeused.IftheoriginalwiringsystemdoesnotmeettheCategory5standard,orifabus-typewiringsystemisusedinsteadofastar-typewiringsystem,thenCategory5linesmustbere-routed.

ToupgradetoGigabitEthernet,youmustfirstupgradethenetworkbackboneswitchtoGigabittoincreasethedatatrafficthatthenetworkbackbonecanwithstand,soastoachievethepurposeofacceleratingthenetworkspeed.Theprevious100Mswitcheswereusedasbranchswitches,andtheprevioushubscanbeusedwherethereareinsufficientwiringpoints.TherearemanyGigabitswitchproducts,whichcanbeselectedaccordingtoactualconditionssuchasnetworkrequirementsandbudgets.

Theserveronthenetworkneedstohandlealotofdata.Ifthenetworkbackboneisupgradedtogigabit,buttheservernetworkcardisstillatthelevelof100M,theservernetworkcardwillbecomethebottleneckofthenetwork,andgigabitmustbeusedThenetworkcardcaneliminatethisbottleneck.Thesolutionistoaddagigabitnetworkcardtotheoriginalserver.Notethat64-bitPCIGigabitnetworkcardsshouldbeselectedfirst,anditsperformanceishigherthanordinaryPCIGigabitnetworkcards.Gigabitnetworkcardcanbeselectedaccordingtoactualconditionssuchasnetworkrequirementsandbudget.

Thebackboneofthenetworkhasbeenupgraded,andthebranchesofthenetworkshouldbeupgradedaccordingly.Iftheoriginalusercomputerhasalreadyinstalleda10M/100Madaptivenetworkcard,youdon’tneedtoupgradethenetworkcard,justconnectthenetworkcardtoa100Mswitch;iftheoriginal10Mbpsnetworkcardisused,youneedtochangethenetworkcardto10M/100Madaptivenetworkcard,soastoincreasethespeedofworkstationsaccessingtheserver.

Prospectforecast

Itisestimatedthatbefore2005,thedatatransmissionvolumewillincreaseby3timeseachyear,andwillexceedthevoicetransmissionvolumethatyear,becomingthemaintransmissionmethodofglobalcommunicationnetwork.Inthefaceofever-increasingdatastreamsandmultimediaservices,themarketscaleofhigh-endnetworkproductswithlarge-capacity,high-speed,andmulti-functionmoduleswillcontinuetoexpand.ItisforeseeablethatthemarketshareofGigabitEthernetswitcheswillbecomelargerandlarger.WiththedevelopmentoftheInternetandtheemergenceofendlessapplicationsonthenetwork,10GigabitEthernetwillbethemainstreaminthefuture,andGigabitEthernetwillstillbethemainstreaminthemarket.

Technicaladvantages

Inordertomaintainthemaximumcollisionareawithadiameterof200metersandtheminimumCSMA/CDcarriertimeinthelocalareanetwork,theEthernettimeslicehasbeenextendedfrom512bitsto512bytes(4096bits),theminimumframelengthbecomes512bytes,andthemaximumframelengthisstill1518bytes.ThecarrierextensionfeaturesolvestheinherenttimingproblemofCSMA/CDwithoutmodifyingtheminimumpacketsize.Althoughthesechangesmayaffecttheperformanceofsmallinformationpackets,thiseffecthasbeenoffsetbyacharacteristiccalledpacketbursttransferintheCSM/CDalgorithm.ThebiggestadvantageofGigabitEthernetisitscompatibilitywithexistingEthernet.

Like100M-bitEthernet,GigabitEthernetusesthesameframeformatandframesizeas10M-bitEthernet,andthesameCSMA/CDprotocol.ThismeansthatthemajorityofEthernetuserscanupgradetheexistingEthernetsmoothlyandwithoutinterruptionwithoutaddingadditionalprotocolstacksormiddleware.Atthesametime,GigabitEthernetalsoinheritsotheradvantagesofEthernet,suchashighreliabilityandeasymanagement.

Comparedwithothertechnologies,GigabitEthernethastheadvantageoflargebandwidthandstillhasroomfordevelopment.Therelevantstandardsorganizationsareformulatingtechnicalspecificationsandstandardsfor10GEthernet.Atthesametime,prioritycontrolmechanismsandprotocolstandardsbasedontheEthernetframelayerandIPlayer,aswellasvariousQoSsupporttechnologieshavegraduallymatured,providingafoundationfortheimplementationofapplicationsrequiringbetterservicequality.Withtheadvancementofopticalfibermanufacturingandtransmissiontechnology,thetransmissiondistanceofGigabitEthernetcanreachupto100kilometers,whichmakesitgraduallybecomeatechnologychoiceforbuildingmetropolitanareanetworksandevenwideareanetworks.

TheadvantageofusingGigabitEthernetinthebackboneisthatGigabitEthernetwillprovide10timestheperformanceofFastEthernetandiscompatiblewiththeexisting10/100Ethernetstandard.Atthesametime,thevirtualnetworkstandard802.1Qandprioritystandard802.1pdevelopedfor10/100/1000Mbpshavebeenpromoted,andthegigabitnetworkhasbecomethemainstreamtechnologythatformsthebackboneofthenetwork.

ThefirstGigabitEthernetstandard802.3,whichwasformulatedinJune1998,targetsfull-duplexlinksusingopticalfibercablesandshort-distancecoppercables.Thestandard802.3abforhalf-duplexandremotecopperwirecableswasintroducedin1999.

Thehigh-speedmulti-layerdatapacketforwardingcapabilityofGigabitEthernetisapowerfulexamplethatGigabitEthernettechnologycanprovidethebestperformance-to-priceratio.Notonlythat,GigabitEthernettechnologyisalsoverybeneficialforreducingthelong-termcostofownershipofthenetwork.

Switchingtechnology

Sincetheendof1996,somecompanieshavesuccessivelyintroducedswitchproductsthatintegratelayer2switchingandlayer3routing.Thistechnologyiscalled"multi-layerswitching(multilayerswitching)".Itaddsroutinglayerservicestolayer2switchingtechnology,supportsselectivebroadcastandmulticastsuppression,supportspacketforwardingandfirewallfunctionsbetweenVLANsandVLANs,andfullysupportsTCP/IPandIPXrouting.

Afternearly4yearsofdevelopment,thesefunctionshavebeencontinuouslyimprovedandstrengthened,makingtheperformance-priceratioofmulti-layerswitches8to16timeshigherthantraditionalrouters.Thenewgenerationofmulti-layerswitcheswithGigabitEthernetswitchingtechnologyasthecore,canprovidemoreattractiveperformance-priceratio,andisthemostidealswitchthatcanprovidemulti-layerswitchingindepartmentalnetworksanddatacenternetworkstoreplacetraditionalrouters.Atthesametime,itsdirecttransmissiondistancehasnowreached130kilometers,whichcanfullyrealizealargeenterpriseLANwithGigabitEthernetasthebackbone,andthebackbonetransmissionrateis2Gbps(fullduplexmode).

ThemainfactorthatpromotesthedevelopmentoftechnologyThebiggestfactorthatpromotesthedevelopmentofhigh-speedmulti-layerswitchingtechnologyisthemassdeploymentoftheInternetandIntranetusingcheap10/100Madaptivenetworkcards.Thenetworkhasbecomefartherandfartherawayfromthetraditionalc/scomputingmodel'shierarchicalstructure,andthetraditional80/20trafficruleofthec/smodelhasbecomeathingofthepast.Intermsofnetworkdesign,thetraditionalrouterplusHuborLayer2switchnetworkdeploymentmodelwillalsobecomehistory.

Intranet navíc podporuje celou řadu složitějších a na šířku pásma citlivých multimediálních datových toků, jako jsou data, soubory, obrázky, animace, zvuk a video. Uživatel intranetu vyžaduje alespoň o 50 % až 100 % větší šířku pásma, než je doba pro připojení intranetového uživatele, Atb.

AnotherissueworthnotingisthatprovidinguserswithafastEthernetconnectioncanprovidemorebandwidthmargintohandlesuddentraffic,whichisunmatchedby10BASE-Ttechnology.BursttrafficisoneofthecharacteristicsofIPnetworkapplications.LowcostandhighbandwidthmakeFastEthernetwidelyusedonboththeusersideandtheserverside.

Inordertostrikeabalancebetweennon-blockingandtheabilitytohandlesuddentrafficflows,thenewgenerationofswitchplatformsmustprovidebackboneconnectionsthatare8-16timesfasterthantheuser’srequestconnection.ThenetworkbackbonejustsatisfiestheservicerequestofthefastEthernetconnectionontheuserside.Thisisveryimportanttoadequatelyhandlebursttraffic.

Atthesametime,incampusnetworksormetropolitanareanetworks,nomatterhowmanynetworklayersarespanned,randomintranettrafficisrequiredtoprovideend-to-endconsistenthighperformance.Inordertoachievethis,itistheonlysolutiontohavebothhigh-performancelayer2andlayer3forwardingcapabilitiesinaswitch.

Thenon-blockingcapabilityandselectiveforwardingfunctionarethemainrequirementsofusers.Variousveryeffectivenetworkmanagementtoolsenablenetworkadministratorstoeffectivelyandefficientlyinjectbusinessstrategiesintotheforwardingengine,anditsperformancecanbemonitoredinrealtimethroughnetworkmanagementsoftware.Thiswillfundamentallyhelpusersdetermineanddelivertherequirednetworkservicesaccordingtothecompany'sshort-termandlong-termbusinessdevelopmentneeds.ThenewgenerationofGigabitEthernetswitchessupportthesefeaturesandservices,aswellascommonroutingprotocolssuchasIP/RIPorIP/OSPF.Thisalsogreatlyreducesthecomplexityofnetworkequipment.

Objectiveprinciples

Thehighperformanceofthenetworksystemrequiresthecoreswitchtomeettherequirementsofthemassivedataexchangeofthenetworkcenter,andthecommunicationlinkbandwidthoftheuplinkcentercanmeettheperformancerequirementsoftheapplicationonthenetwork.Regardlessofwhetheritisanenterprisenetwork,ametropolitanareanetwork,orawideareanetwork,theinformationapplicationsonitaredevelopingatanunprecedentedspeed,andnewmultimediaapplicationsandnewdataapplicationsplacehigherrequirementsonbandwidth.Inthecaseofenterprisesgenerallyadoptingtheintranetnetworkmodel,itsWWWserver,FTPserver,LotusNotesgroupwareapplicationserver,NovellServerandotherserverclusterssupporttheentireenterprise'sinformationserviceenvironment.Theclientapplicationsoftwareofusersinvariousdepartmentsoftheenterpriseaccessesthecentralserverthroughthenetwork,requestsapplications,andqueriesthedatabase.Theloadflowofthenetworkismainlythedataexchangefromtheedgedevicetothecore.Withthedevelopmentofenterprisebusiness,theexpansionofthenetworkscale,andtheincreaseintheamountofinformationexchangeoftheapplication,theenterprisenetworkusuallyfirstoccursinthecoreofthecommunicationbottleneckphenomenon.ToimprovethenetworkdataexchangeperformanceoftheenterprisecampusLAN,thefirststepistoexpandtheexchangeperformanceofthecoreswitchandincreasethedatacommunicationbandwidthfromtheedgedevicetothecoretoreducethebottleneckoftheentirenetworkandimprovetheperformanceandefficiencyofapplicationsoftware.Therefore,intheprincipleofdesigninganenterprisecampusLAN,weshouldfirstconsiderthedataexchangeprocessingcapabilitiesofthecoreequipmentrequiredbythenetworkscale,andthelinkbandwidthfromtheedgeequipmenttothecore.

Reliabilityandavailability

Thehighreliabilityofequipmentandhighavailabilityofthesysteminthenetworksystemdesign;allkeycomponentsofthecoreswitcharerequiredtoachieveredundancyandcanbereplacedonline(plug),therecoverytimeofthefaultiscompletedwithinasecondinterval.Themulti-levelfault-tolerantdesignfurtherimprovestheavailabilityofthesystembasedonthehighreliabilityofasingledevice.

Asfarasenterpriseapplicationsareconcerned,itusesadvancedcomputer,networkandotherinformationtechnologiestorealizeautomaticcontroloftheproductionprocessandpaperlessofficeautomation,whichimprovestheefficiencyandlevelofproductionandmanagementoftheenterprise.Theinfrastructuresupportingenterpriseapplicationsistheenterprise'scampusnetwork.Itsworkingconditionswilldirectlyaffecttheenterprise'sofficeapplicationenvironment,businessenvironmentsuchastransaction,production,development,design,financialmanagement,partsmanagementandotherenvironments,informationretrieval,databasequery,Internetbrowsingandothernecessaryservicefacilitiestosupportthenormaloperationoftheenterprise.Thereliabilityrequirementofthenetworkistheprimaryconditiontoensurethenormaloperationoftheenterpriseapplicationenvironment.Whilethenetworkrequiresreliability,italsorequiresthenetworktohavehighavailability.Thechoiceofnetworkequipment,especiallythecorechassis-typeequipment,shouldbeabletoconfigureredundantcomponents.Thereisnosinglepointoffailureforkeycomponents.Thatistosay,componentssuchasswitchpowersupplies,fans,switchingengines,andmanagementmodulescanberedundantlybackedup.Thedamageofanypartofoneofthemwillnotaffectthenormaloperationoftheequipmentandwillnotaffectthenetworkconnection.Anotherrequirementforthereliabilityandfaulttoleranceofthenetworkequipmentisthatwhenthedamagedpartsoftheequipmentarereplaced,thereisnoneedtoshutdown,andthereisnoneedtorestartafterreplacingtheparts.Thatistosay,thereplacementofthepartscanbeoperatedonline,whichcanreducethedowntime.Tothesmallest.Ontheprincipleofdesigningenterprisecampusnetworks,itisveryimportanttoimprovetheprinciplesofhighreliabilityandhighavailabilityofthenetwork.Notonlytheequipmentcomponentsarerequiredtoberedundant,butalsothenetworklinkredundancyisrequired,whichcancombinethephysicallayer,linklayerandThethirdlayeroftechnologyisimplementedtoensurethatthenetworkcanprovideinformationaccessservicesatanytimeandanyplace.

Scalability

Thescalabilityrequirementsofnetworkdesignincludethescalabilityofswitchhardwareandtheabilityofthenetworktoimplementnewapplications.Flexiblescalabilityrequirementsforcoreswitches:Thecoreswitchesshouldhaveflexibleportexpansioncapabilitiesandmoduleexpansioncapabilitiestomeettheexpansionofnetworkscale;atthesametime,improveperformancetomeethigherperformancerequirements.Abilitytosupportnewapplications:Theproducthasthetechnicalpreparationtosupportnewapplications,andcanimplementnewapplicationsquicklyandeasily.

title="Gigabit Ethernet">

Scaleandusers

Whendesigninganetworkplan,thefirstthingtodoistomeettheneedsofnetworkusersoftheexistingscale.Atthesametime,consideringfuturebusinessdevelopmentandscaleexpansion,thenetworkshouldbedesignedIthasflexibleexpansioncapabilitiesforuserports.Thecoreequipmentisthehuboftheentirenetwork.Theexpansionofthenumberofuserportsrequirestheadditionofequipmentintheedgeworkinggroupofthewiringcloset.Whentheedgeequipmentisadded,thenumberofportsconnectedtothecorebackboneequipmentisrequiredtoincreaseaccordingly.Therefore,thecoreequipmentshouldbeabletoincreasethenumberofmodules.Toflexiblyincreasethenumberofports.Thechassisdesignofthecoreequipmentshouldhaveastrongbackplanebandwidthandenoughloadslotcapacity.Fortheswitch,thecoreswitchingengineshouldbeabletoperformportdatapacketswitchingwithoutblockingunderthemaximumconfiguration,andtheexpansionofthemoduledoesnotaffecttheswitchingperformance.Theuseofadistributedswitchingstructureisthebestsolutiontorealizethisprinciple.Thedistributedswitchstructurerealizestheparalleldataexchangeprocessingoftheswitchesandoptimizestheperformanceofthenetwork.Thedistributedstructurecombininglocalandglobalswitchingreducesthecoreswitchingengine.pressure.Therefore,intheprincipleofdesigninglarge-scalecampusnetworks,distributedswitchesaregenerallyusedtoachieveflexiblemoduleandportexpansioncapabilities.

Security

Networksecurityisveryimportanttonetworkdesign.Reasonablenetworksecuritycontrolcaneffectivelyprotectandcontroltheinformationresourcesintheapplicationenvironment.Networkaccess,flexibleimplementationofnetworksecuritycontrolstrategies.Intheenterprisecampusnetwork,onlysystemadministratorshavethepowertooperateandcontrolkeyapplicationserversandcorenetworkequipment.Theapplicationclientonlyhastherighttoaccesssharedresources,andthenetworkshouldbeabletopreventanyillegaloperations.Itshouldbepossibletoperformpacketfilteringcontrolfunctionsbasedonprotocol,Macaddress,andIPaddressonthecampusnetworkequipment.Inthedesignoflarge-scalecampusnetworks,dividingvirtualsubnetscaneffectivelyisolatealargenumberofbroadcastsinthesubnetsontheonehand,andontheotherhandisolatethecommunicationbetweennetworksubnets,controlresourceaccessrightsandimprovenetworksecuritysex.Inthedesignofthecampusnetwork,thesecuritycontrolcapabilityofthenetworkmustbeemphasized,sothatthenetworkcanbeconnectedarbitrarily,andtheaccesstothenetworkcanbecontrolledfromthesecondandthirdlayers.

Manageability

Networkmanageabilityrequirements:anydeviceinthenetworkcanbecontrolledthroughthenetworkmanagementplatform,andnetworkequipmentstatus,faultalarms,etc.canallbemanagedthroughthenetworkmanagementTheplatformperformsmonitoring,simplifiesmanagementthroughthenetworkmanagementplatform,andimprovestheefficiencyofnetworkmanagement.

Innetworkdesign,itisessentialtochooseadvancednetworkmanagementsoftware.Networkmanagementsoftwareisusedinnetworkequipmentconfiguration,networktopologydisplay,networkequipmentstatusdisplay,networkequipmentfailureeventalarm,networktrafficstatisticsanalysisandbilling,etc.Theapplicationofnetworkmanagementsoftwarecanimprovetheefficiencyofnetworkmanagementandreducetheburdenonnetworkmanagementpersonnel.Thegoalofnetworkmanagementistoachievezeromanagement,astrategy-basedmanagementmethod,andnetworkmanagementisgloballycontrolledbythemanagementstrategyserverbyformulatingaunifiedstrategy.Theweb-basednetworkmanagementinterfaceisthedevelopmenttrendofnetworkmanagementsoftware,andtheflexibleoperationmodesimplifiestheworkofmanagementpersonnel.Inthedesignofthecampusnetworkequipmentselection,thenetworkequipmentisrequiredtosupportthestandardnetworkmanagementprotocolSNMP,whilesupportingtheRMON/RMONIIprotocol,andthecoreequipmentisrequiredtosupporttheRAP(remoteanalysisport)protocoltoimplementsufficientnetworkmanagementfunctions.Inprinciple,thedesignofthecampusnetworkshouldrequirethemanageabilityofequipment,whileadvancednetworkmanagementsoftwarecansupportnetworkmaintenance,monitoring,configurationandotherfunctions.

Standardizationoftheprotocol

Networkequipmentadoptsopentechnologyandsupportsstandardprotocols:standardprotocolsareusedtoprotectusers’investmentandimproveequipmentinteroperability.Theequipmentusedinnetworkdesignrequiresmainstreamtechnologyanddevelopedstandardprotocols,hasgoodinteroperability,andcansupportdifferentseriesofproductsofthesamemanufacturer,andseamlessinterconnectionandcommunicationbetweenproductsofdifferentmanufacturers.Ontheprincipleofdesigningthecampusnetwork,thespecialadvancedtechnologyofdifferentmanufacturers'productsmustbeused,andthestandardizationofequipmenttechnologyandprotocolmustbeemphasizedtoreduceequipmentinterconnectionproblemsandnetworkmaintenancecosts,sothatuserinvestmentcanbeeffectivelyprotected.

Itshouldbeconsideredwhethertheselectedequipmentisupgradeable.Afterthenewstandardappears,thesystemshouldbeabletoupgradetothenewstandard.Therefore,focusonthestatusofproductmanufacturersinthecorrespondingproductandtechnicalfieldsandtheirabilitytoparticipateinstandardization.

Intoday'sworld,thedevelopmentofcommunicationtechnologyandcomputertechnologyischangingwitheachpassingday.Networkdesignmustnotonlyadapttothetrendofnewtechnologydevelopment,ensuretheadvancednatureofthesystem,butalsotakeintoaccountthetechnicalmaturity,andreducetheriskscausedbyimmaturefactorsinnewtechnologiesandnewproducts.

Řešení

Největší výhodou Gigabit Ethernetu je kompatibilita s existujícím Ethernetem. Jako 100M-bitEthernet,GigabitEthernet používá stejný formát rámce a rámy velikosti 10M-bitEthernet.

Asafeatureofcampusnetworkapplications,mostapplicationsarenotsensitivetodelayandbandwidth,andcanautomaticallyidentifydelaychangesthroughtheTCP/IP"slowstart"mechanism,anddynamicallyadapttothebandwidthprovidedbyTCP,Someapplicationsrequirereal-timeservicetransmissionsupportandQoSserviceguarantee.Thispartoftheapplicationaccountsforasmallproportion.Withtheaccelerationofthemodernizationofteachingmethods,thegradualpopularizationofmultimediacoursewareproductiontools,andthegradualenrichmentofmultimediacourseware,theproportionisexpectedtograduallyincrease.Themainbottleneckofreal-timeservicetransmissionoverIPnetworkisthatroutersusesoftwaretorealizerouteidentification,calculationandpacketforwarding.Duetotheslowspeedofrouteidentificationanddataforwarding,thedelayanddelayjitterarelarge,thequalityofservice(QoS)cannotbeguaranteed.Sincethesecondhalfof1997,somecompanieshavesuccessivelyintroducednewwire-speedroutingswitchesthatusehardwarededicatedcircuits(ASIC)forroutingidentification,calculation,andforwarding.Thestructureofthiswire-speedroutingswitchissimilartothatoftheL2switch.IthasboththeL3routerpacketforwardingfunctionandtheL2switchingfunction.SomemanufacturersalsoaddsomeL4applicationlayerfunctions.

ToprovideQoSonthepacket-switchedIPnetwork,theservicemustbeclassified,andtheclassificationservice(CoS)mustbeimplemented.Equipmentmanufacturersgenerallyusecongestionmanagementtoensurenetworkperformanceandprovidetherequiredbandwidthforsomespecializedservices.OneapproachistouseRED(RandomEarlyLoss)todetectandintelligentlyidentifytheinstantaneoussurgeintraffictodistinguishitfromrealnetworkcongestiontoavoidnetworkcongestion.Byidentifyingtheservicecategory(802.1P)fromtheIPv4serviceclassificationidentifier(TOS)intheIPpacketheader,thepriorityofthedataflowisdetermined,andacertainqueuepriorityalgorithmisusedtoensuretheQoScapability.Youcanalsouseanaccesscontrollist(ACL)todefinepoliciesanddeterminethepriorityofdatastreams.Withtheadvancementoftechnology,itisforeseeablethatQoScapabilitiesonhigh-speedIPnetworkswillreachasimilarlevelofFR/ATMnetworks.

Onthebasisofanalyzingandcomparingtheperformance,price,andserviceofavarietyofL2/L3/L4wire-speedroutingswitchesinthemarket,atotalof11CajunP550RroutingswitchesfromLucent(Lucent)wereselectedasthecampusNetworkbackboneswitch.Itsmaintechnologyandperformanceindicatorsare:

Kapacita základní desky 45,76 Gb/s

Přepínací propustnost 22,88 Gb/s

Kapacita přepínání vrstvy 33 000 000 stran za sekundu

Kapacita přepínání vrstvy 18 000 000 pps

Více modulů rozhraní L2/L3

Redundantní ventilátory, napájecí zdroje

Interoperabilita OpenTrunk/VLAN

Podpora CoS/QoS/RSVP

Innetworkdesign,backboneswitchesareinterconnectedwitheachotherthroughGigabitEthernet.AllswitchesareequippedwithL3switchingenginetoimplementdistributedroutingstrategies,therebyreducingthepressureonL3routinganalysisandpacketforwardingofthecentralswitchandcontrollingthescopeofthebroadcastdomain.Thenetworkdesignandequipmentconfigurationcarefullyconsiderthephysicalandlogicalredundancyofequipment,linesandrouting,thefirewallsettingsandsecuritypoliciesofthenetworkcenterservergroup.

Technologie

Technologie 1000Base

S vydáním národní technické specifikace pro přepínací zařízení GigabitEthernet byla aplikace technologie vyvinuta mílovými kroky.

1000Base-T(GigabitEthernetimplementedonCategory5twistedpair)hasbecomeoneofthebestchoicesfornetworkmanagersduetothefollowingreasons.First,itmainlymeetstherapidlyincreasingdemandforbandwidthinexistingnetworks;secondly,inthesenetworks,emergingapplicationscontinuetoappear,andswitchesattheedgeofthenetworkarealsoincreasing.GigabitEthernetcanprotectthecompany'sexistinginvestmentsinEthernetandFastEthernetfacilities;third,itcanprovideasimple,effectiveandinexpensiveperformanceimprovementmethod,whilecontinuingtousealargenumberofexistingHorizontalcabletransmissionmedium.

Princip technologie 1000Base-T

Transmissionmediaspecification

GigabitEthernetcanusetheexistingcablefacilities,sothatithasagoodperformancepriceCompare.Itcanbeusedonthenetworkinfloors,buildingsandcampusesbecauseitcansupportmultipleconnectionmediaandawiderangeofconnectiondistances.Inparticular,GigabitEthernetcanrunonthefollowingfourmedia:opticalfiber,withamaximumconnectiondistanceofatleast5kilometers;Modularfiber,withamaximumconnectiondistanceofatleast550meters;balanced,shieldedcoppercable,withamaximumconnectiondistanceofatleast25meters;Category5lines,withamaximumconnectiondistanceofatleast100meters.

TheIEEE802.3zGigabitEthernetstandardwasapprovedinJune1998.Itdefinesthreetransceiversforthreetransmissionmedia:1000Base-LX,1000Base-SXand1000Base-CX.Amongthem,1000Base-LXisusedtoinstallsingle-modeopticalfiber,1000Base-SXisusedtoinstallmulti-modeopticalfiber,and1000Base-CXisusedtobalanceandshieldcoppercables.Itcanbeusedforinterconnectionincomputerrooms.1000Base-LXtransceiverscanalsobeusedformultimodeopticalfibers,withatransmissiondistanceofatleast550meters.

GigabitEthernetLayering

Anotherspecialworkinggroup,IEEE802.3abhasdefinedthephysicallayerforrunningGigabitEthernetonthebasisofCategory5lines.TheIEEEStandardizationCommitteeapprovedthe1000Base-TstandardinJune1999.1000Base-Tcancontinuetousetheexistingcablefacilities,anditstipulatesthatthetransmissiondistanceontheCategory5linecanbeupto100meters.

Některé další důležité specifikace technologie 1000Base-Tmake italow, těžko rozbitné a vysoce výkonné technologie.Za prvé podporuje EthernetMACa je zpětně kompatibilní s technologií Ethernet 10/100Mbps;zadruhé mnoho 1000Base-Tproduktů,0může0podporovat0000napodruhé. prošel rychlou sítí Ethernet Upgrade; třetí, vysoce výkonná technologie 1000 Base-Tisah, přenáší 10 miliard bitů, z nichž bude více než jeden nový datový bit (bitová chyba je menší než 10-10, což je stejné jako bitová chyba 100Base-T, bitová chyba je srovnatelná).

Specifikace kabelu

1000Base-T je testem, že data lze přenášet do vyvážených kroucených kabelů kategorie 5. Norma ANSI/EIA/TIA-568-A(1995) specifikuje výkon čtyřpárových pětiotáčkových měřidel v kategorii IA a používá se EL-pár Twisted pair. -TSB-95.Standard pro kabely kategorie5stanovenývISO/IEC11801:1995 ("Informační technologie: Obecné kabely pro uživatelská přední zařízení"). Druhé vydání normy ISO/IEC11801:1995 specifikuje některé další parametry výkonu kabelu pro podporu GigabitEthernet.

Fyzická struktura

1000Base-Tisspeciálně navržená pro přenos dat na kabelech s kroucenými páry kategorie 5. Přenosová rychlost 1 Gbps může být ekvivalentně považována za čtyři páry zkroucených párů a přenosová rychlost každého páru je 250 Mbps × 45).

1000Base-Tand100Base-Tusethesametransmissionclockfrequency(125MHz),butuseamorepowerfulsignaltransmissionandencoding/decodingscheme,whichcanbecomparedto100Base-TonthelinkTtransmitstwiceasmuchdata.Thefollowingisacomparisonofthesetwotechnicalspecifications:

1000Base-T:125MHz×2bit=250Mbps

1000Base-TX:125MHz×2bit-symbol=125Mbit-symbol/s

Všimněte si: 125Mbits-symbol/s ekvivalentem 100Mbps,protože 1000Base-Tusesa4B/5Bencoding-před vložením signálu do kabelu pro přenos, každé 4bityData jsou převedena na 5bitové-symboly; efektivní přenos je 0 × 5 bitů = 1 Mbps.

1000Base-Tencoding

Za účelem nákladově efektivního používání 4 až 5 typů UTP, IEEE802.3 nepoužívá 8B/10 kódování, ale definuje logiku v podvrstvě MAC a v každé vrstvě PHYRozhraní umožňuje zavedení nejlevnějších pásem s efektivním kódováním do každého schématu kategorie 5UTP by neměla překročit 125 Mbaud (když je kategorie 5UTP 62,5 MHz, její ACR je 30,6 dB). Kód je přijat, tedy 8B/4Quinary. Tímto způsobem může (1000/4)×(4/8)=125 Mbaud splnit omezení dostupné šířky pásma.

Použije se čtyřúrovňové (kvartérní) kódování, výše uvedené požadavky mohou být splněny a mohou také pokrýt 28=256, ale pro další čtyři úrovně lze použít kód pro opravu chyb v pětiúrovňovém (quinárním) kódování.

Poslední 1000Base-T whitepaper GigabitEthernetAlliance doporučuje použití PAM-5kódu,každýsymbol(vezmětejedenz+2,+1,0,-1,-2)odpovídá dvěma číslicímBinární-chyba-8dimenzionálního stavu. Realizace těchto chyb závisí především na technologii integrovaných obvodů a technologii zpracování digitálního signálu (DSP).

1000Base-TcansupporttheexistingFastEthernetandV.90/56Kmodemtechnologiesthathavebeentestedinpractice,therebyachievingagoodperformance-priceratio.AdvancedDSPsthatimplementsignaltransmissionandencoding/decodingtechniquesin802.3FastEthernetandV.90or56Kmodemscanalsobeusedtoimplement1000Base-T.

Vývojové výhody

GigabitEthernetisanewtypeofhigh-speedlocalareanetwork,whichcanprovide1Gb/scommunicationbandwidth,andadopts10/100MEthernethasthesameCSMA/CDprotocol,frameformatandframelength,soitcanachieveasmoothandcontinuousnetworkupgradeonthebasisoftheoriginallow-speedEthernet,whichcanmaximizetheprotectionoftheuser'spreviousinvestment.

Conclusion

AsmoreandmoredesktopcomputersandworkgroupsupgradetoFastEthernet,thecentralizedbusinessofthebackboneofthenetworkwillincreasesubstantially.Inordertohandlethiskindofbusiness,allnewbackboneswitchesshouldsupportGigabitEthernetuplinks.GigabitEthernetswitchesinthebackbonenetworkcanbeusedtoconnecthightransactionrateserversandnetworksegmentswitchesforcentralizedFastEthernetworkinggroups.IftheopticalfibernetworkconnectionmodeofGigabitEthernetsolvesthehigh-speedconnectionbetweenbuildings,then1000Base-TGigabitEthernettechnologyisusedtosolvethehigh-speedconnectionbetweenfloorsandevenbetweenoffices.

Ostatní typy

Standardní Ethernet

Na začátku má Ethernet pouze propustnost 10 Mb/sa má vícenásobný přístup s detekcí kolize (CSMA/CD,CarrierSenseMultipleAccess/Collisioncontrol,thereDetection0th) Ethernet může používat silný koaxiální kabel, tenký koaxiální kabel, nestíněný kroucený pár, stíněný kroucený pár a optické vlákno a další přenosová média pro připojení a ve standardu IEEE802.3 byla formulována různá přenosová média .Normy fyzické vrstvy. V těchto normách přední číslo označuje přenosovou rychlost, jednotka "Mbps", poslední číslo označuje délku jednoho segmentu síťového kabelu (základní jednotka 100 m), Základní znamená "základní pásmo" a Širokopásmové znamená "širokopásmové".

·10Base-5používá silný koaxiální kabel o průměru 0,4 palce a impedanci 50Ω, také známý jako silný kabel Ethernet, maximální délka segmentu sítě je 500 m, metoda přenosu základního pásma, topologie je typ sítě, včetně typu E; 10Base karta se zásuvkou AUI, opakovač, transceiver, vysílač s přijímačem, terminátor atd.

·10Base-2používákoaxiální kabel o průměru 0,2 palce a impedanci 50Ω, také známý jako tenký kabel Ethernet. Maximální délka segmentu sítě je 185 m, metoda přenosu v základním pásmu a topologie sítě je typ sběrnice; okket, opakovač, T-konektor, terminátor atd.

·10Base-Tusestwisted-pair kabel,maximální délka segmentu sítě je 100m a topologie je ve tvaru hvězdy;hlavní hardwarové vybavenísítě 10Base-Tobsahuje:Kategorie3neboKategorie5nestíněný kroucený pár,kabelyRJ-4 s rozbočovači,RJ-5kartyR atd.

·1Base-5použitý kroucený-párový kabel,maximální délka segmentu sítě je 500m a přenosová rychlost je 1Mbps;

·10Broad-36používá koaxiální kabel (RG-59/UCATV), maximální rozsah sítě je 3600 m a maximální délka segmentu sítě je 1800 m, což je širokopásmová přenosová metoda;

·10Base-Fuses optické přenosové médium a přenosová rychlost je 10Mbps.

FastEthernet

Withthedevelopmentofthenetwork,thetraditionalstandardEthernettechnologyhasbeenunabletomeettheincreasingdemandfornetworkdatatrafficspeed.BeforeOctober1993,forLANapplicationsrequiringdatatrafficabove10Mbps,onlytheopticalfiberdistributeddatainterface(FDDI)wasavailable,butitwasaveryexpensiveLANbasedon100Mpbsopticalcable.InOctober1993,GrandJunctionlaunchedtheworld'sfirstfastEthernethubFastch10/100andnetworkinterfacecardFastNIC100,andthefastEthernettechnologywasofficiallyapplied.Subsequently,Intel,SynOptics,3COM,BayNetworksandothercompanieshavealsolaunchedtheirownfastEthernetdevices.Atthesametime,theIEEE802engineeringgroupalsoconductedresearchonvariousstandardsof100MbpsEthernet,suchas100BASE-TX,100BASE-T4,MII,repeater,fullduplexandotherstandards.InMarch1995,IEEEannouncedtheIEEE802.3u100BASE-TFastEthernetstandard(FastEthernet),andthusbegantheeraofFastEthernet.

ComparedwiththeoriginalFDDIworkingat100Mbpsbandwidth,FastEthernethasmanyadvantages.ThemostimportantthingisthatFastEthernettechnologycaneffectivelyprotecttheuser’sinvestmentintheimplementationofwiringinfrastructure.ItsupportsTheconnectionofcategory3,4,5twistedpairandopticalfibercaneffectivelyutilizetheexistingfacilities.TheshortcomingsofFastEthernetareactuallytheshortcomingsofEthernettechnology,thatis,FastEthernetisstillbasedonCSMA/CDtechnology.Whenthenetworkloadisheavy,itwillcauseadecreaseinefficiency.Ofcourse,thiscanbecompensatedbyswitchingtechnology.The100MbpsfastEthernetstandardisdividedintothreesub-categories:100BASE-TX,100BASE-FX,and100BASE-T4.

·100BASE-TX:isafastEthernettechnologythatusesCategory5data-levelunshieldedtwistedpairorshieldedtwistedpair.Itusestwopairsoftwistedpairs,onepairforsendingandonepairforreceivingdata.The4B/5Bencodingmethodisusedinthetransmission,andthesignalfrequencyis125MHz.ComplywithEIA586'sCategory5wiringstandardandIBM'sSPTCategory1wiringstandard.UsethesameRJ-45connectoras10BASE-T.Itsmaximumnetworksegmentlengthis100meters.Itsupportsfull-duplexdatatransmission.

·100BASE-FX:ItisakindoffastEthernettechnologythatusesfiberopticcable,whichcanusesingle-modeandmulti-modefiber(62.5and125um).Themaximumdistanceofmultimodefiberconnectionis550meters.Themaximumdistanceofsingle-modefiberconnectionis3000meters.The4B/5Bencodingmethodisusedinthetransmission,andthesignalfrequencyis125MHz.ItusesMIC/FDDIconnector,STconnectororSCconnector.Itsmaximumnetworksegmentlengthis150m,412m,2000morlongerto10kilometers,whichisrelatedtothetypeoffiberusedandworkingmode,anditsupportsfull-duplexdatatransmission.100BASE-FXisparticularlysuitableforapplicationsinenvironmentswithelectricalinterference,large-distanceconnections,orhigh-securityenvironments.

·100BASE-T4:ItisakindoffastEthernettechnologythatcanuse3,4,5typesofunshieldedtwistedpairorshieldedtwistedpair.100Base-T4uses4pairsoftwistedpairs,ofwhichthreepairsareusedtotransmitdataatafrequencyof33MHz,andeachpairworksinhalf-duplexmode.ThefourthpairisusedforCSMA/CDconflictdetection.The8B/6Tencodingmethodisusedinthetransmission,andthesignalfrequencyis25MHz,whichconformstotheEIA586structuredwiringstandard.ItusesthesameRJ-45connectoras10BASE-T,andthemaximumnetworksegmentlengthis100meters.

10GigabitEthernet

Specifikace 10Gigabitového Ethernetu je zahrnuta v doplňkovém standardu IEEE802.3ae standardu IEEE802.3.Itext ukončuje protokol IEEE802.3 a specifikaci MAC0, aby podporovala přenos 10Gb/spřenosu přes WIN(interface,podvrstvu:1. síťový kanál lze upravit na nižší přenosovou rychlost, například 9,584640 Gb/s (OC-192), což umožňuje 10gigabitové ethernetové zařízení kompatibilní se synchronní optickou sítí (SONET) STS - 192c přenosový formát.

·10GBASE-SRa10GBASE-SW podporuje hlavně krátkovlnné (850nm)multivláknové vlákno (MMF) a vzdálenost vlákna je 2m až 300m.

10GBASE-SRmainlysupports"darkfiber".Darkfiberreferstoanopticalfiberthathasnolightpropagationandisnotconnectedtoanyequipment.

10GBASE-SW se používá hlavně k připojení zařízení SONET a používá se pro vzdálenou datovou komunikaci.

·10GBASE-LRa10GBASE-LWpodporuje hlavně dlouhovlnné (1310nm)jednomódové vlákno (SMF) se vzdáleností 2m až 10km (asi 32 808 stop).

Když se k připojení zařízení SONET používá hlavně 10GBASE-LW,

10GBASE-LRse používá k podpoře "tmavého vlákna".

·10GBASE-ERa10GBASE-EWpodporuje hlavně ultra-dlouhé vlny (1550nm) jedno-módové vlákno (SMF) se vzdáleností 2m až 40km (přibližně 131 233 stop).

10GBASE-EW se používá hlavně k připojení zařízení SONET,

10GBASE-ERse používá k podpoře "tmavého vlákna".

·10GBASE-LX4useswavelengthdivisionmultiplexingtechnologytosendsignalsatfourtimestheopticalwavelengthonasinglepairofopticalcables.Thesystemrunsunder1310nmmulti-modeorsingle-modedarkfibermode.Thedesigngoalofthissystemisforthemulti-modefibermodefrom2mto300morthesingle-modefibermodefrom2mto10km.

△Ethernetové připojení

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