外文翻译校园网络多媒体的演变.docx
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外文翻译校园网络多媒体的演变.docx
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外文翻译校园网络多媒体的演变
一、英文原文:
TheEvolutionofCampusNetworksTowardsMultimedia
CiroA.NoronhaJr.FouadA.Tobagi
4TheBackbone
Thecampusbackbonecarriestheaggregatetrafficfromthesubnetworks.Fromatheoreticalpoint,ofview,thedesignofthebackboneisnodifferent,fromthedesignofthesubnetworksthemselves;thestepstakeninsection3canberepeatedhere,withthedifferencethatthenetworkbeingdesignedisthebackbone,andits"users"arethesubnetworks.Thedifferenceisoneofscale.Inthissection,wewillbrieflycommentontheeffectofthebackbonetrafficontheaggregatethroughputofthesubnetwork(whichwasignoredinsection3),andthencomputethebackbonetrafficunderavarietyofscenarios.
4.1ConnectingtheSubnetworktotheBackbone
Themaindifferencebetweenthetrafficto/fromthebackboneandtheinternalsubnetworktrafficisthefactthatformerisconcentratedinasinglepoint(thebackboneconnection);inotherwords,allthetrafficfromthethesubnetworktothebackboneisdirectedtothebackboneconnection,andallthetrafficfromthebackbonetothesubnetworkoriginatesinthesamelocation.Intheotherhand,thesourcesanddestinationsoftheintra-subnetworktrafficarespreadoverthesubnetwork.
Theeffectofaddingthebackboneconnectionintheaggregatesubnetworkbandwidth'dependsonitstopology.Insubnetworksorganizedastrees,thecongestioninthebranchesnearthelocationofthebackboneconnectionmightlimittheaggregatethroughputtoavaluelowerthanwhatisattainedwhennobackbonetrafficispresent.Inthestarconfiguration,however,thehigh-speedchannelistheideallocationforattachingthebackboneconnection,andtheaggregatethroughputinthiscaseisalwayshigherthanitsvaluewhenthereisnotrafficfromthebackbone.Thereasonforthisissimple:
theinternalsubnetworktrafficusesbandwidthbothatthesourceandatthedestinationsegments,butthetrafficto/fromthebackboneusesbandwidthonlyatthesource/destinationsegments,leadingtoahigheraggregatethroughput.
Theactualincreaseordecreaseintheaggregatebandwidthwillbeafunctionofa,thefractionofthetrafficthat,isintra-subnetwork,andA,theratiobetweenthetrafficfromthebackbonetothetrafficintothebackbone(definedinsection2.).Theincreaseishigherforsmallvaluesofa(mostofthetrafficisintersubnetwork).
4.2StructureoftheBackbone
Inthissection,wewillgiveanumberofscenariosthatillustratehowthestructureofthebackbonecanchangeasafunctionofthesizeofthecampusnetwork;wewillusefigure3todeterminetherequiredcapacity.Theresultsareshownintable1;notethatthesolutionsforthestructureofthebackbonearenotunique,andwehavelistedoneofsuchsolutionsforeachcase.
Infigure5weshowonepossiblebackbonetopologywhichhasallthemainelementswehavebeendiscussing.Inthefigureweshowthesubnetworksbeingservedbyswitchinghubs.TheswitchinghubsservingsubnetworkswithlittleexternaltrafficcanbegroupedbyanATMmultiplexerbeforereachingtheATMswitch;thismultiplexercanperformsomelocalswitchingorrelycompletelyinthecentralswitch.HubsgeneratinglargertrafficcanbeconnecteddirectlytotheATMswitch.Theswitchisalsothebestlocationtoconnectcentralizedsharedresources,suchasvideoservers.TheATMswitchesthemselvescanbearrangedinahierarchicalfashion,dependingonthetrafficrequirements.
5AddingmultimediatotheotherOSIlayers
InthissectionwediscusstheissuesraisedbytheadditionofmultimediaservicesontheotherlayersoftheOSImodel.
5.1TheMediumAccessControl(MAC)Layer
Thesynchronousnatureofaudioandvideotrafficdictatesthatdatabedeliveredtoitsdestinationwithinstricttimingconstraints.Failuretodeliverdataontimeresultsinadiscontinuityofthevideooradegradationinthequality.Thebustynatureofdatatraffic,ontheotherhand,meansthatastationtransmitsdatainanunpredictablefashion,andtheamountofdatathatthestationtransmitsinaburstisalsorandom.
Bothtypesoftrafficaretobesupportedbythesamelocalnetwork.Indeed,multimediaapplicationsnaturallyinvolvebothtypesoftrafficsimultaneously;existinglocalareanetworksareexpectedtocarryaudioandvideotrafficalongsideexistingdataapplications.Mixingthetwotypesoftrafficonthesamenetworkrequiresspecialattention,particularlywheresharedresourcesarecontendedtobybothtypes.Thebandwidthavailableonlocalareanetworksegmentsisonesuchsharedresource,andisthesubjectofthissection.Itissharedbyalltrafficoriginatingatallstations,andaccessedbymeansoftheMediaAccessControl(MAC)protocol.Ideally,onewouldliketheMACprotocoltoincludetechniqueswhichreservethebandwidthnecessaryforsynchronoustraffic,soastoremoveanyeffectofbustytraffic.
TheCSMA/CDprotocol(IEEE802.3)doesnotdifferentiateamongthedifferenttraffictypes.Inessence,itoperatesasfollows.Astationwithapacketreadyfortransmissiontransmitsthepacketassoonasthechannelissensedidle.Ifitcollideswithanotherpacket,thenitattemptsagainbutafterincurringarandomreschedulingdelay.Themeanreschedulingdelayisdoubledwitheachcollisionincurred.Thisisclearlyinadequateforreal-timetraffic.Notonlyisthedelayincurredbypacketsnondeterministic,butitsvarianceisquitelarge,owingtotheexponentialbackoffalgorithm.However,sinceatlowloadsthisprotocolworkswell,itcanstillbeusedifonesegmentsthenetworktoinsurethatthisconditionismet.
IEEE802.5isatokenprotocoldevisedforaringnetwork.Itusesasingletoken,inthesensethatastationthathascompletedtransmissionwillnotissueanewtokenuntilthebusytokenreturnstoit.Sinceinaringnetworktheconnectiontothemediumisactive,apriorityschemecanbeimplementedbyassigningdynamicallyapriorityvaluetothetoken,andbyrestrictingaccesstotheringtopacketsofpriorityequalorhigherthanthecurrentlyassignedvalue.Thisschemecanbeappropriatelyusedtointegratethetwotypesoftrafficonthesamechannelsimplybygivingsynchronoustraffichigherprioritythanthebustydatatraffic.
InFDDI(ANSIX3T9.5),anotherschemewithmultipleprioritylevelsisemployed,bytheuseofasetoftimers,thatregulateforhowlongthestationcantransmittrafficofeachpriority.
Insummary:
theassignmentofdifferenttypesofserviceforreal-timeanddatatrafficattheMAClayerisveryimportantwhencommunicatingmultimediainformation.ThisisnotofferedinthewidelydeployedIEEE802.3Othernetworks,suchastheIEEE802.5tokenringandFDDIcanprovidethisfunctionality,althoughmanyvendorshavechosennottoimplementit.Giventhelargebaseofdeployednetworks,itisnotreasonabletoexpectthatchangesintheMAClayertosupportmultimediawouldbeimplemented.Therefore,onemustseekotheroptions(suchasmakingsurethatthenetworkoperateswithlowenoughloadthattheproblemsdescribedinthissectionwillnotbeseen).
5.2TheNetworkLayer
Asthechangesdescribedbeforetakeplaceinthenetwork,theroutetousewhenmovinginformationfromsegmenttosegmentbecomesincreasinglyimportant.Insimpletopologies,suchasstarwiththeswitchingelementinthecenter,routingistrivialbecausethereisonlyoneroutefromthesourcetothedestination.However,inpracticemultipleroutesmightbeprovidedbetweenagivenpairofstations,forreliabilityand/orincreased.
Currently,thepathtakenbyapacketfromitssourcetoitsdestinationthroughthenetworkisdeterminedbythebridgesandroutersthatdefinethenetworktopology.Transparentbridgesusethespanningtreealgorithm,i.e.,thebridges,workingtogether,identifyasubsetofthenetworktopologythatconstitutesaspanningtree,anddirectalltrafficthroughthisspanningtree.Linksnotonthespanningtreearenotusedandkeptinreserve,tobeactivatedincaseoffailureofalinkinthespanningtree.Moreover,thespanningtreeidentifiedforatopologyisessentiallychosenatrandom,anditisnotoptimuminanysense.Thishastwoconsequences:
first,extracapacityontheredundantlinksisneverused;andsecond,bottlenecksmaydevelopduetotrafficconcentrationinsomesegments,asaresultoftheparticularspanningtreechosen.Wehavediscussedthistrafficconcentrationinsection3.
Routers,ontheotherhand,havetheabilitytousemultiplespanningtrees;asamatteroffact,eachrouterforwardsthepacketsoverthespanningtreehavingitselfastheroot.Manyalgorithmsexisttocomputethoseroutesinadistributedfashion(RIP,OSPF,IS-IS,etc),buttheyallemploythecostofthelinkasthemetricusedwhencomputingthespanningtree(thecostofalinkisanarbitraryfunction,inverselyproportionaltothelink’sbandwidth).Routerscanrecoverfromnetworkfailures,andcanmakeuseofthebandwidthofalllinksavailable.However,inmostcases,allthetrafficbetweenasourceandadestinationwillbesentoverthesameroute.Moreover,current,routershavenoprovisionfortakingintoaccountreal-timerequirements(suchasdelay)whencomputingroutes,andthesystemofprioritiesimplementedisclearlyinadequateformultimediacommunications.
Ofspecialimportanceistheroutingofmulticasttraffic(video-conferenceisanexampleofasituationwherethiskindoftrafficisgenerated).Formulticasttraffic,twokindsofroutescanbeidentified:
minimumdelayroutesandminimumcostroutes.Currentmulticastroutersusetheminimumdelaycriteriontocomputetheroutes,butthismightleadtou
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