Features • ComplianttoXFPMSA• Compliant to IEEE 802.3ae 10GBASE-LR for 10GbE,
10.3125Gb/s• Compliantto10GFC1310nmSerialPMD,type1200-
SM-LL-L,10.51875Gb/s• Compatiblewith11.3GoperationforFECfunctionality• AvagoTechnologies’uncooled1310nmDFBLaserand
PINPhotodiode• CompliantXFI10GSerialelectricalinterface• LCDuplexopticalconnectorinterfaceconformingto
ANSITIA/EIA604-10(FOCIS10)• 1.5Wtypicalpowerdissipation• Superior Thermal and EMI integrity performance to
supporthighportdensities• Customizableclip-onheatsinktosupportavarietyof
linecardenvironments• -5to+70°Ccaseoperatingtemperaturerange• Capableofextendedtemperature(-10Cto+85Ccase)
operation**• Hardwarepinsareavailableforthefollowingcontrol
signals: -Transmitterdisable -Modulepowerdown/RESET -Receiverlossofsignal -Modulenotready -Programmableinterrupt• 2-wireserialmanagementinterfaceprovidesrealtime
monitorsof: -TransmittedOpticalPower -ReceivedOpticalPower -LaserBiasCurrent -ModuleTemperature• LinkLengthsupto10kmwith9µmfiber• IEC60825-1Class1/CDRHClass1lasereyesafety.
**Note:Longtermreliabilityatelevatedtemperaturesisnotguaranteed.
DescriptionThe1310nmXFPtransceiverisahighperformance,costeffectivemoduleforserialopticaldatacommunicationsapplicationsspecifiedforsignalratesof10.30Gb/sto10.52Gb/s.It iscomplianttoXFPMSARev4.5.Themoduleisdesignedforsinglemodefiberandoperatesatanominalwavelengthof1310nm.Thetransmittersectionincorpo-ratesAvagoTechnologies’uncooleddirectlymodulated1310 nm distributed feedback laser (DFB).The receiversection uses AvagoTechnologies’ MOVPE grown planarSEDETPINphotodetectorforlowdarkcurrentandexcel-lentresponsivity.IntegratedTxandRxsignalcondition-ersprovidehigh jitter-tolerancefor fullXFIcompliance.TheinternallyaccoupledhighspeedserialI/Osimplifiesinterfacing to external circuitry.The electrical interfaceismadeusinganindustrystandard0.8mmpitch30-pinrightangleconnector.OpticalconnectionismadeviatheduplexLCconnector.
Applications• FiberChannelSwitches• HostBusAdapterCards• MassStorageSystemandServerI/O• EthernetSwitches• CoreRouters
HFCT - 721 XPD10GbE/10GFC 1310 nm XFP 10 Gbit/s Optical Transceiver
Data Sheet
The product also offers digital diagnostics using the 2-wireserialinterfacedefinedintheXFPMSA.Theproductprovidesrealtimetemperature(moduleandlaser),supplyvoltage,laserbiascurrent,laseraverageoutputpowerandreceivedinputpower.Thedigitaldiagnosticinterfacealsoaddstheabilitytodisablethetransmitter(TX_DIS),powerdownthemodule,monitorformodulefaultsandmonitorforReceiverLossofSignal(RX_LOS).Transmitterdisable,interrupt,powerdown/reset, receiver lossofsignalandmodulenotreadyarealsohardwiredpinsonthe30-pinrightangleconnector.
Installation
TheHFCT-721XPDcanbeinstalledinanyXFPportregard-lessofhostequipmentoperatingstatus.TheHFCT-721XPDis hot-pluggable, allowing the module to be installedwhilethehostsystemisoperatingandon-line.Theclip-onheatsinkisdesignedtoclipontotheXFPcagewithoutamodulepresent.
Upon insertion, the transceiver housing makes initialcontactwiththehostboardXFPcage,mitigatingpotentialdamageduetoElectro-StaticDischarge(ESD).Oncefullyinserted into the XFP cage, the top surface of the XFPmodulemakescontactwiththeheatsinkthroughacutoutinthetopofthecageensuringaneffectivethermalpathformoduleheat.
Functional Description
Transmitter Section
Thetransmittersectionincludesa1310nmDFB(Distrib-uted Feedback Laser) light source, a transmitter drivercircuit and a signal conditioner circuit on the TX datainputs.(seeFigure1)Opticalconnectiontothetransmit-terisprovidedviaaLCconnector.TheopticaloutputiscontrolledbyacustomICthatdetectsthelaseroutputviathemonitorphotodiode.ThisICprovidesbothdcandaccurrentdrivetothelasertoensurecorrectmodulation,eyediagramandextinctionratioovertemperature,supplyvoltageandoperatinglife.
TX_DIS
Assertingpin5,TX_DIS,willdisablethetransmitteropticaloutput.Thetransmitteroutputcanalsobedisabledandmonitoredviathetwo-wireserialinterface.
Eye Safety Circuit
Undernormaloperatingconditions laserpowerwillbemaintained below Class 1 eye-safety limits. Should acatastrophiclaserfaultoccurandopticalpowerbecomeuncontrolled, the micro-controller will detect the fault,shutdownthelaser,powerdownthemoduleandassertthehard-wiredMOD_NRflag.TheTX_FAULToutputinthe2-wireserialinterfacewillalsobeasserted.
Figure 1. Transceiver Functional Diagram
PIN
Laser RFdriver
CWdriver
Opt
ical
rece
ptac
les
Elec
tric
al c
onne
ctor
Mon. PIN
ROSA
TOSAEEPROM
Microcontroller
A/D
ESA
Heat sink
Ana
log
sign
al
cond
ition
ers
Main housing
Analog bus
Digital 10Gb/s electricalI/O
Digital lowspeed bus orsignal
Analog signal
Powersupply
control
TIATIA
+.VSignal
Conditioner
Signal
Conditioner
Receiver Section
ThereceiversectionincludesaPINdetectorwithamplifica-tionquantizationsignalconditionercircuits.(seeFigure1)OpticalconnectiontothereceiverisprovidedviaaLCopticalconnector.
RX_LOS
The receiver section contains a loss of signal (RX_LOS)circuit to indicate when the optical input signal powerisinsufficientforreliablesignaldetection.Ahighsignalindicateslossofmodulatedsignal,indicatinglinkfailuresuchasabrokenfiberornonfunctionalremotetransmit-ter.RX_LOScanalsobemonitoredviathetwo-wireserialinterface(byte110,bit1).
XFP Module
Host Board
OptionalHost +5 V
4.7 µH VCC5
0.1 µF 22 µF 0.1 µF
Host +3.3 V 4.7 µH VCC3
0.1 µF 22 µF 0.1 µF
OptionalHost +1.8 V
4.7 µH VCC2
0.1 µF 22 µF 0.1 µF
OptionalHost -5.2 V
4.7 µH VEE5
0.1 µF 22 µF 0.1 µF
GND
XFP
Con
nect
or
Figure 2. MSA recommended power supply filter
Electrical Pinout
GND
RD-
RD+
GND
VCC2
P_DOWN/RST
VCC2
GND
REFCLK+
REFCLK-
GND
GND
TD-
TD+
GND
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
GND
RX_LOS
MOD_NR
MOD_ABS
SDA
SCL
VCC3
VCC3
GND
VCC5
TX_DIS
INTERRUPT
MOD_DESEL
VEE5
GND
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
TOWARDASIC
TOWARDBEZEL
Figure 4. Host PCB XFP Pinout Top View
Functional Data I/O
AvagoTechnologies’HFCT-721XPDfiber-optictransceiverisdesignedtoaccept industrystandardelectrical inputdifferentialsignals.Thetransceiverprovidesac-coupled,internally terminated data input and output interfaces.Biasresistorsandcouplingcapacitorshavebeenincludedwithinthemoduletoreducethenumberofcomponentsrequiredonthecustomer’sboard.
Table 1. Electrical Pin Definitions
Pin Name Logic Function/Description Notes
1 GND ModuleGround 1
2 VEE5 -5.2Vpowersupply.Notinternallyconnected.
3 Mod-Desel LVTTL-I ModuleDe-select;Whenheldlowallowsthemoduletorespondto2-wireSerialinterfacecommands
4 Interrupt LVTTL-O Interrupt;Indicatespresenceofanimportantconditionwhichcanbereadovertheserial2-wireinterface 2
5 TX_DIS LVTTL-I TransmitterDisable;TransmitterLaserSourceTurnedOff
6 VCC5 5Vpowersupply.Notinternallyconnected.
7 GND ModuleGround 1
8 VCC3 +3.3VPowerSupply
9 VCC3 +3.3VPowerSupply
10 SCL LVTTL-I TwoWireInterfaceClock 2
11 SDA LVTTL-I/O TwoWireInterfaceDataLine 2
12 Mod_Abs LVTTL-O LVTTL-OMod_AbsIndicatesModuleisnotpresent.GroundedintheModule 2
13 Mod_NR LVTTL-O ModuleNotReady;IndicatingModuleOperationalFault 2
14 RX_LOS LVTTL-O ReceiverLossOfSignalIndicator 2
15 GND ModuleGround 1
16 GND ModuleGround 1
17 RD- CML-O ReceiverInvertedDataOutput
18 RD+ CML-O ReceiverNon-InvertedDataOutput
19 GND ModuleGround 1
20 VCC2 +1.8VPowerSupply.Notinternallyconnected.
21 P_Down/RST LVTTL-IPowerdown:Whenhigh,themoduleisputintoalowerpowermode.Serialinterfaceisfunctionalinthelowpowermode.Reset:ThefallingedgeinitiatesacompleteresetofthemoduleincludingtheserialInterface,equivalenttoapowercycle.
22 VCC2 +1.8VPowerSupply.Notinternallyconnected. 1
23 GND ModuleGround
24 RefCLK+ PECL-I ReferenceClockNon-InvertedInput,accoupledonthehostboard 3
25 RefCLK- PECL-I ReferenceClockInvertedInput,accoupledonthehostboard 3
26 GND ModuleGround 1,3
27 GND ModuleGround 1
28 TD- CML-I TransmitterInvertedDataInput
29 TD+ CML-I TransmitterNon-InvertedDataInput
30 GND ModuleGround 1
Notes:1. ModulegroundpinsGndareisolatedfromthemodulecaseandchassisgroundwithinthemodule.2. OpenCollectorshouldbepulledupwith4.7K-10Kohmstoavoltagebetween3.15Vand3.6Vonthehostboard.3. RefCLK+/-areinternallyterminated(50Ω)
Absolute Maximum Ratings
Parameter Symbol Minimum Typical Maximum Unit Notes
StorageTemperature(non-operating) TS -40 +85 °C 1,2
AmbientOperatingTemperature TA -40 +85 °C 1,2
RelativeHumidity RH 10 90 % 1
SupplyVoltage VCC3 0 3.6 V 1,2
LowSpeedInputVoltage VIN -0.5 VCC+0.5 V 1
Parameter Symbol Minimum Typical Maximum Unit Notes
PowerSupplyNoiseRejection(peak-peak)under1MHz
PSNR 2%ofVCC mV 5
PowerSupplyNoiseRejection(peak-peak)1MHzto10MHz
PSNR 3%ofVCC mV 5
Modulesupplycurrent ICC 680 mA
PowerDissipation PDISS 1.5 2100 mW
Low Speed Outputs:MOD_NR,RX_LOS,MOD_ABS,INTERRUPT
VOHVOL
Host_VCC-0.50.0 0.01
Host_VCC+0.30.4
VV
67
Low Speed Inputs:TX_DIS,MOD_DESEL,P_DOWN/RST
VIHVIL
2.0-0.3
VCC3+0.30.8
VV
89
Parameter Symbol Minimum Typical Maximum Unit Notes
CaseOperatingTemperature TC -5 +70 °C 3
SupplyVoltage VCC3 3.135 3.465 V 4,5
DataRate 9.953 10.52 Gb/s 4
OpticalInputPowerMax Pinmax 6 dBm 1,2
Notes:1. AbsoluteMaximumRatingsarethosevaluesbeyondwhichdamagetothedevicemayoccuriftheselimitsareexceededforotherthanashort
periodoftime.SeeReliabilityDataSheetforspecificreliabilityperformance.2. BetweenAbsoluteMaximumRatingsandtheRecommendedOperatingConditionsfunctionalperformanceisnotintended,devicereliability
isnotimplied,anddamagetothedevicemayoccuroveranextendedperiodoftime.3. TheAmbientOperatingTemperaturelimitationsarebasedontheCaseOperatingTemperaturelimitationsandaresubjecttothehostsystem
thermaldesign.4. RecommendedOperatingConditionsarethosevaluesforwhichfunctionalperformanceanddevicereliabilityisimplied5. VccconditionappliestosupplyvoltageattheXFPmodule6. FilterperXFPspecificationisrequiredonthehostboard.7. 4.7kto10kW resistorpull-uptohost_VCC,measuredatthehostsideofconnector.IOH(max)=-2mA.8. 4.7kto10kW resistorpull-uptohost_VCC,measuredatthehostsideofconnector.IOL(max)=2mA.9. 4.7kto10kW resistorpull-uptohost_VCC,measuredatthehostsideofconnector.IOL(max)=10µA.10.4.7kto10kW resistorpull-uptohost_VCC,measuredatthehostsideofconnector.IIH(max)=-10µA.
Transceiver Electrical Characteristics(TC=-5°Cto+70°C,VCC3=3.3V±5%)
Recommended Operating Conditions
Transmitter Electrical Input Characteristics(TC=-5°Cto+70°C,VCC3=3.3V±5%)
Parameter Symbol Minimum Typical Maximum Unit Notes
DifferentialInputImpedance Zd 100 W
TerminationMismatch DZM 5 %
DifferentialInputAmplitude DVQDO 120 820 mV peaktopeak(1)
DifferentialInputReturnLoss SDD11 20 dB 0.05to0.1GHz
DifferentialInputReturnLoss SDD11 8 dB 0.1to5.5GHz
DifferentialInputReturnLoss SDD11 8-20.66log10(f/5.5)finGHz
dB 5.5-12GHz
CommonModeInputReturnLoss SCC11 3 dB 0.1to15GHz
DifferentialtoCommonModeConversion SCD11 -10 dB 0.1to15GHz
JitterandEyeMask XFPMSACompliant
Parameter Symbol Minimum Typical Maximum Unit Notes
DifferentialInputImpedance Zd 100 W
TerminationMismatch DZM 5 %
DifferentialOutputAmplitude 340 850 mV peaktopeak(1)
DCCommonModePotential Vcm 0 3.6 V
OutputACCommonModeVoltage 15 mV RMS
OutputRise/Falltime(20%to80%) tRH,tFH 24 ps
Commonmodeoutputreturnloss SCC22 3 0.1to15GHz
Differentialoutputreturnloss SDD22 20 dB 0.05to0.1GHz
Differentialoutputreturnloss SDD22 8 dB 0.1to5.5GHz
Differentialoutputreturnloss SDD22 8-20.66log10(f/5.5)finGHz
dB 5.5-12GHz
JitterandEyeMask XFPMSACompliant
Receiver Electrical Output Characteristics
Note:1. ThedifferentialinputandoutputamplitudesareperXFPMSAmaskatpointsB’andC’.
Transmitter Optical Characteristics 10 GbE/10GFC(TC=-5°Cto+70°C,VCC3=3.3V±5%)
Parameter Symbol Minimum Typical Maximum Unit Notes
OpticalOutputPower Pout -5.2 dBmOMA 1,2
AverageOpticalOutputPower Pout -8.2 0.5 dBm 1,2,3
ExtinctionRatio ER 3.5 dB 1,2
SpectralWidth-rms s,rms 0.2 nmRMS 3
CenterWavelength λC 1260 1310 1355 nm
Transmitteranddispersionpenalty TDP 3.2 dB 1,3
Sidemodesuppressionratio 30 dB 1
Opticaloutputpower(min)inOMA-TDP -6.2 dBmOMA 1,3
RIN12(OMA) RIN -128 dB/Hz 1
OpticalEyeMask CompliantwithIEEE802.3ae10GBASE-LXFPMSA
Parameter Symbol Minimum Typical Maximum Unit Notes
AverageReceivepower -14.4 0.5 dBmmean 1
Stressedreceiversensitivity -10.3 dBmOMA 1
Receiversensitivity PIN -12.6 dBmOMA 3
MaxReceiverReflectance -12 dB 1
Wavelength λC 1260 1310 1355 nm
Notes:1. 10GFC1200-SM-LL-L/IEEE802.3ae10BASE-LRcompliant2. Theseparametersareinterrelated:seeIEEE802.3ae3. Forinformationonly
Receiver Optical Characteristics 10 GbE/10GFC(TC=-5°Cto+70°C,VCC3=3.3V±5%)
Transceiver Timing Characteristics(TC=-5°Cto+70°C,VCC3=3.3V±5%)
Parameter Symbol Minimum Typical Maximum Unit Notes
TX_DISAssertTime t_off 10 µs TimefromrisingedgeofTX_DIStowhentheopticaloutputfallsbelow10%ofnominal.
TX_DISNegateTime t_on 2 ms TimefromfallingedgeofTX_DIStowhenthemodulatedopticaloutputrisesabove90%ofnominal.
Timetoinitialize t_init 300 ms Frompoweronorhotplugaftermeetingpowersupplyspecs
Interruptassertdelay Interrupt_on 200 ms Fromoccurrenceoftheconditiontriggeringinterrupt
Interruptnegatedelay Interrupt_off 500 us Fromclearonreadinterruptflags
P_Down/RSTassertdelay
P_Down/RST_on
100 us FromPowerdowninitiation
P-Downnegatedelay P_Down/RST_off
300 ms Maxdelayfromnegatetocompletionofpowerupandreset
Mod_NRassertdelay Mod_nr_on 1 ms FromOccurrenceoffaulttoassertionofTX_NR
Mod_NRnegatedelay Mod_nr_off 1 ms FromOccurrenceofsignaltonegationofTX_NR
Mod_DeSelasserttime T_Mod_DeSel 2 ms MaximumdelaybetweenassertionofMod_DeSelandendofmoduleresponseto2-wireinterfacecom-munications
Mod_DeSelde-asserttime
T_Mod_Sel 2 ms Maximumdelaybetweende-assertionofMod_DeSelandpropermoduleresponseto2-wireinterfacecommunications
P_Downresettime t_reset 10 µs MinlengthofP-Downasserttoinitialreset
RX_LOSAssertdelay T_loss_on 100 µs FromOccurrenceoflossofsignaltoassertionofRX_LOS
RX_LOSnegatedelay T_loss_off 2.3 100 µs FromOccurrenceofpresenceofsignaltonegationofRX_LOS
SerialIDClockRate f_serial_clock 0 400 kHz
Digital Diagnostic Interface and Serial Identification
The2-wireserialinterfaceisexplicitlydefinedintheXFPMSARev4.0.2-wiretimingspecificationsandthestructureofthememorymapareperXFPMSARev2.0.Thenormal256ByteI2Caddressspaceisdividedintolowerandupperblocksof128Bytes.Thelowerblockof128BytesisalwaysdirectlyavailableandisusedfordiagnosticinformationprovidingtheopportunityforPredictiveFailureIdentifica-tion,CompliancePrediction,FaultIsolationandCompo-nentMonitoring.TheupperaddressspacetablesareusedforlessfrequentlyaccessedfunctionssuchasserialID,userwriteableEEPROM,reservedEEPROManddiagnosticsandcontrolspacesforfuturestandardsdefinition,aswellasAvagoTechnologies-specificfunctions.
Predictive Failure Identification
The diagnostic information allows the host system toidentifypotentiallinkproblems. Onceidentified,a“failover”techniquecanbeusedtoisolateandreplacesuspectdevicesbeforesystemuptimeisimpacted.
Compliance Prediction
The real-time diagnostic parameters can be monitoredtoalertthesystemwhenoperatinglimitsareexceededandcompliancecannotbeensured.Asanexample,therealtimeaveragereceiveopticalpowercanbeusedtoassess the compliance of the cable plant and remotetransmitter.
Fault Isolation
Thediagnosticinformationcanallowthehosttopinpointthelocationofalinkproblemandacceleratesystemser-vicingandminimizedowntime.
Component Monitoring
Aspartofhostsystemqualificationandverification,realtimetransceiverdiagnosticinformationcanbecombinedwithsystemlevelmonitoringtoensureperformanceandoperatingenvironmentaremeetingapplicationrequire-ments.
Transceiver Internal Temperature
TemperatureismeasuredontheHFCT-721XPDusingsens-ingcircuitrymountedontheinternalPCB.ThemeasuredtemperaturewillgenerallybecoolerthanlaserjunctionandwarmerthanXFPcaseandcanbeindirectlycorrelatedtoXFPcaseorlaserjunctiontemperatureusingthermalresistanceandcapacitancemodeling.Thismeasurementcanbeusedtoobservedriftsinthermaloperatingpointortodetectextremetemperaturefluctuationssuchasafailureinthesystemthermalcontrol.Formoreinforma-tiononcorrelatinginternaltemperaturetocaseorlaserjunctioncontactAvagoTechnologies.
Transmitter Laser dc Bias Current
Laserbiascurrentismeasuredusingsensingcircuitrylo-catedonthetransmitterlaserdriverIC.Normalvariationsin laser bias current are expected to accommodate theimpactofchangingtransceivertemperatureandsupplyvoltageoperatingpoints.TheHFCT-721XPDusesaclosedlooplaserbiasfeedbackcircuittomaintainconstantopticalpower.Thiscircuitcompensatesfornormallaserparametricvariationsinquantumefficiency,forwardvoltageandlasingthresholdduetochangingtransceiveroperatingpoints.
Transmitted Average Optical Output Power
VariationsinaverageopticalpowerarenotexpectedundernormaloperationbecausetheHFCT-721XPDusesaclosedlooplaserbiasfeedbackcircuittomaintainconstantopticalpower.Thiscircuitcompensatesfornormallaserparametricvariationsduetochangingtransceiveroperatingpoints.Onlyunderextremelaserbiasconditionswillsignificantdriftingintransmittedaverageopticalpowerbeobserv-able. Therefore it is recommended Tx average opticalpowerbeusedforfault isolation,ratherthanpredictivefailurepurposes.
Received Average Optical Input Power
Receivedaverageopticalpowermeasurementsareavalu-ableassetforinstallerstoverifycableplantcompliance.Driftsinaveragepowercanbeobservedfromthecableplant and remote transmitter for potential predictivefailureuse.Receivedaverageopticalpowercanbeusedforfaultisolation.
10
Figure 5b. Module Drawing
Mechanical Specifications
Package Dimensions
Figure 5a. Module Drawing
11
Figure 6. XFP host board mechanical layout
1
Figure 7. XFP Assembly Drawing
Clip
Host Board
Heat Sink
Cage Assembly
Module
Bezel
EMI Gasket(not shown)
Connector
1
Application Support
AnEvaluationKitandReferenceDesignsareavailabletoassistinevaluationoftheHFCT-721XPD.Pleasecontactyour localFieldSalesrepresentativeforavailabilityandorderingdetails.
Regulatory Compliance
ThetransceiverRegulatoryComplianceperformance isprovidedinTable2asafigureofmerittoassistthede-signer.Theoverallequipmentdesignwilldeterminethecertificationlevel.
Electrostatic Discharge (ESD)
TherearetwoconditionsinwhichimmunitytoESDdam-ageisimportant.Table13documentstheESDimmunitytobothoftheseconditions.
Regulatory Compliance
Thefirstcondition isstaticdischargetothetransceiverduringhandlingsuchaswhenthetransceiverisinsertedintothetransceiverport.Toprotectthetransceiver,itisimportanttousenormalESDhandlingprecautionsinclud-ingtheuseofgroundedwriststraps,workbenches,andfloor mats in ESD controlled areas. The ESD sensitivityoftheHFCT-721XPDiscompatiblewithtypicalindustryproductionenvironments.
Thesecondconditionisstaticdischargetotheexteriorofthehostequipmentchassisafter installation. Totheextent that the duplex LC optical interface is exposedtotheoutsideofthehostequipmentchassis,itmaybesubjecttosystem-levelESDrequirements.
TheESDperformanceoftheHFCT-721XPDexceedstypicalindustrystandards.
Feature Test Method Performance
ElectrostaticDischarge(ESD)totheexterioroftheXFPmodule
JEDECJESD22-A114-B 500Voltstothehighspeedpins,2000Voltstothelowspeedpins
ElectrostaticDischarge(ESD)totheDuplexLCReceptacle
VariationofIEC61000-4-2 Typically,nodamageoccurswith25kVwhentheduplexLCconnectorreceptacleiscontactedbyaHumanBodyModelprobe.
ElectrostaticDischarge(ESD)totheOpticalConnector
GR1089 10contactsof8KVontheelectricalfaceplatewithdeviceinsertedintoapanel.
ElectrostaticDischarge(ESD)totheOpticalConnector
VariationofIEC801-2 Airdischargeof15kV(min)contacttoconnectorw/odamage
ElectromagneticInterference(EMI)
FCCClassBCENELECEN55022ClassB(CISPR22A)VCCIClass1
Systemmarginsaredependentoncustomerboardandchassisdesign.
Immunity VariationofIEC61000-4-3 Lessthan0.5dBofRxsensitivitydegradationandlessthan10%marginreductionofTxmaskat10V/m,10MHZto1GHzw/ochassisenclosure
LaserEyeSafetyandEquipmentTypeTesting
USFDACDRHAELClass1US21CFR,SubchapterJperParagraphs1002.10and1002.12.
(IEC)EN60825-1:1994+A11+A2(IEC)EN60825-2:1994+A1(IEC)EN60950:1992+A1+A2+A3+A4+A11
CDRHcertification#TBDTUVfile#933/510312/02
ComponentRecognition UnderwritersLaboratoriesandCanadianStandardsAssociationJointComponentRecognitionforInformationTechnologyEquipmentIncludingElectricalBusinessEquipment
ULcertificatenumber05012004-E173874
Immunity
Thetransceivershaveashieldeddesigntoprovideexcellentimmunitytoradio-frequencyelectromagneticfieldswhichmaybepresentinsomeoperatingenvironments.
Electromagnetic Interference (EMI)
Most equipment designs using the HFCT-721XPD aresubject to the requirements of the FCC in the UnitedStates,CENELECEN55022(CISPR22)inEuropeandVCCIinJapan.ThemetalhousingandshieldeddesignoftheHFCT-721XPDminimizesEMIandprovidesexcellentEMIperformance.
Eye Safety
TheHFCT-721XPDtransceiversprovideClass1eyesafetybydesign.AvagoTechnologieshastestedthetransceiverdesignforregulatorycompliance,undernormaloperat-ing conditions and under single fault conditions. SeeTable2.
Flammability
TheHFCT-721XPDiscomplianttoUL94V-0.
Caution
The HFCT-721XPD contains no user serviceable parts.Tampering with or modifying the performance of theHFCT-721XPDwillresultinvoidedproductwarranty. ItmayalsoresultinimproperoperationoftheHFCT-721XPDcircuitry,andpossibleoverstressofthelasersource.Devicedegradation or product failure may result. Connectionof theHFCT-721XPDtoanon-approvedopticalsource,operatingabovetherecommendedabsolutemaximumconditions may be considered an act of modifying ormanufacturingalaserproduct.Theperson(s)performingsuchanactisrequiredbylawtorecertifyandreidentifythe laser product under the provisions of U.S. 21 CFR(SubchapterJ)andtheTUV.
Ordering Information
Pleasecontactyour localfieldsalesengineeroroneofAvagoTechnologiesfranchiseddistributorsfororderinginformation.Fortechnicalinformation,pleasevisitAvagoTechnologies’WEBpageatwww.avagotech.comorcontactAvagoTechnologiesSemiconductorProductsCustomerResponseCenterat1-800-235-0312.Forinformationre-latedtoXFPMSAdocumentationvisitwww.xfpmsa.org
For product information and a complete list of distributors, please go to our web site: www.avagotech.com
Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies, Pte. in the United States and other countries.Data subject to change. Copyright © 2006 Avago Technologies Pte. All rights reserved. Obsoletes 5989-2468EN AV01-0237EN - June 15, 2006
