Quad Low-Power, 500Mbps ATE Driver/Comparator
19-3016; Rev 2; 5/06Quad Low-Power, 500MbpsATE Driver/ComparatorThe MAX9965/MAX9966 four-channel, low-power, highspeed pin electronics driver and comparator ICsinclude for each channel a three-level pin driver, comparator, and variable clamps. The MAX9965/MAX9966are similar to the MAX9963/MAX9964, but with evenlower window comparator dispersion for enhancedaccuracy. The driver features a wide voltage range andhigh-speed operation, includes high-Z and active termination (3rd-level drive) modes, and is highly linear evenat low-voltage swings. The dual bipolar-input comparator provides very low dispersion (timing variation) over awide variety of input conditions. The clamps providedamping of high-speed DUT waveforms when thedevice is configured as a high-impedance receiver.High-speed, differential control inputs compatible withECL, LVPECL, LVDS, and GTL levels are provided foreach channel. ECL/LVPECL or flexible open-collectoroutputs are available for the comparators.The A-grade version provides tight matching of gainand offset for the driver and comparator, allowing reference levels to be shared across multiple channels incost-sensitive systems. For system designs that incorporate independent reference levels for each channel,the B-grade version is available at reduced cost.Optional internal resistors at the high-speed inputs provide differential termination of LVDS inputs, whileoptional internal resistors provide the pullup voltageand source termination for open-collector comparatoroutputs. These features significantly reduce the discrete component count on the circuit board.The MAX9965/MAX9966 operating range is -1.5V to 6.5V, with powerdissipation of only 975mW per channel.These devices are available in a 100-pin, 14mm x14mm body, 0.5mm pitch TQFP with an exposed 8mmx 8mm die pad on the top (MAX9965) or bottom(MAX9966) of the package for efficient heat removal.The MAX9965/MAX9966 are specified to operate withan internal die temperature of 60 C to 100 C, andfeature a die temperature monitor output.ApplicationsMemory TestersLow-Cost Mixed-Signal/System-on-Chip TestersStructural TestersPattern/Data GeneratorsFeatures Small Footprint: Four Channels in 0.4in2 Low Power Dissipation: 975mW/Channel (typ) High Speed: 500Mbps at 3VP-P Very Low Timing Dispersion Wide Operating Range: -1.5V to 6.5V Active Termination (3rd-Level Drive) Low-Leakage Mode: 15nA Maximum Integrated Clamps Interface Easily with Most Logic Families Digitally Programmable Slew Rate Internal Logic Termination Resistors Low Gain and Offset ErrorOrdering InformationPARTTEMP RANGEMAX9965ADCCQ*0 C to 70 C100 TQFP-EPR***PIN-PACKAGEMAX9965AKCCQ*0 C to 70 C100 TQFP-EPR***MAX9965AGCCQ*0 C to 70 C100 TQFP-EPR***MAX9965AHCCQ*0 C to 70 C100 TQFP-EPR***MAX9965AJCCQ*0 C to 70 C100 TQFP-EPR***MAX9965BDCCQ*0 C to 70 C100 TQFP-EPR***MAX9965BKCCQ*0 C to 70 C100 TQFP-EPR***MAX9965BGCCQ0 C to 70 C100 TQFP-EPR***MAX9965BHCCQ*0 C to 70 C100 TQFP-EPR***MAX9965BJCCQ0 C to 70 C100 TQFP-EPR***MAX9966ADCCQ*0 C to 70 C100 TQFP-EP**MAX9966AKCCQ*0 C to 70 C100 TQFP-EP**MAX9966AGCCQ*0 C to 70 C100 TQFP-EP**MAX9966AHCCQ*0 C to 70 C100 TQFP-EP**MAX9966AJCCQ*0 C to 70 C100 TQFP-EP**MAX9966BDCCQ*0 C to 70 C100 TQFP-EP**MAX9966BKCCQ*0 C to 70 C100 TQFP-EP**MAX9966BGCCQ0 C to 70 C100 TQFP-EP**MAX9966BHCCQ*0 C to 70 C100 TQFP-EP**MAX9966BJCCQ*0 C to 70 C100 TQFP-EP***Future product—contact factory for availability.**EP Exposed pad.***EPR Exposed pad reversed.Pin Configurations and Selector Guide appear at end of datasheet.Maxim Integrated ProductsFor pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.1MAX9965/MAX9966General Description
MAX9965/MAX9966Quad Low-Power, 500MbpsATE Driver/ComparatorABSOLUTE MAXIMUM RATINGSVCC to GND .-0.3V to 11.5VVEE to GND.-7.0V to 0.3VAll Other Pins .(VEE - 0.3V) to (VCC 0.3V)VCC - VEE .-0.3V to 18VDUT to GND.-2.5V to 7.5VDATA , NDATA , RCV , NRCV to GND .-2.5 to 5.0VDATA to NDATA . . . 1.5VRCV to NRCV . 1.5VVCCO to GND . -0.3V to 5VSCLK, DIN, CS, RST to GND . -1.0V to 5VDHV , DLV , DTV , CHV , CLV to GND .-2.5V to 7.5VCPHV to GND .-2.5V to 8.5VCPLV to GND.-3.5V to 7.5VDHV to DLV . 10VDHV to DTV . 10VDLV to DTV . 10VCHV or CLV to DUT . 10VCH , NCH , CL , NCL to GND.-2.5V to 5VCurrent into DHV , DLV , DTV ,CHV , CLV , CPHV , CPLV . 10mACurrent into TEMP .-0.5mA to 20mADUT Short Circuit to -1.5V to 6.5V . .ContinuousPower Dissipation (TA 70 C)MAX9965 CCQ (derate 167mW/ Cabove 70 C) .13.3W*MAX9966 CCQ (derate 47.6mW/ Cabove 70 C) .3.8W*Storage Temperature Range .-65 C to 150 CJunction Temperature . . 125 CLead Temperature (soldering, 10s) . . 300 C*Dissipation wattage values are based on still air with no heat sink for the MAX9965 and slug soldered to board copper for the MAX9966.Actual maximum power dissipation is a function of users’ heat extraction technique and may be substantially higher.Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functionaloperation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure toabsolute maximum rating conditions for extended periods may affect device reliability.ELECTRICAL CHARACTERISTICS(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note 1)PARAMETERSYMBOLCONDITIONSMINTYPMAXUNITSPOWER SUPPLIESPositive SupplyVCC9.59.7510.5VNegative SupplyVEE-6.5-5.25-4.5VPositive SupplyICC(Note 2)200225mANegative SupplyIEE(Note 2)-370-425mAPower DissipationPD(Notes 2, 3)3.94.5W 6.5VDUT CHARACTERISTICSOperating Voltage Range MaxVDUTLeakage Current in High-Z ModeIDUTLeakage Current in Low-LeakageModeIDUT(Note 4)-1.5LLEAK 0, 0 VDUT 3V 2LLEAK 0, VDUT -1.5V, 6.5V 5LLEAK 1, 0 VDUT 3V, TJ 90 C 15LLEAK 1, VDUT -1.5V,TJ 90 C 30LLEAK 1, VDUT 6.5V, TJ 90 CµAnA 30Driver in term mode (DUT DTV )3Driver in high-Z mode5Low-Leakage Enable Time(Notes 5, 7)20µsLow-Leakage Disable Time(Notes 6, 7)20µsLow-Leakage RecoveryTime to return to the specified maximumleakage after a 3V, 4V/ns step at DUT(Note 7)10µsCombined Capacitance2CDUTpF
Quad Low-Power, 500MbpsATE Driver/Comparator(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note 1)PARAMETERSYMBOLCONDITIONSMINTYPMAXUNITS 25µALEVEL PROGRAMMING INPUTS (DHV , DLV , DTV , CHV , CLV , CPHV , CPLV )Input Bias CurrentIBIASSettling TimeTo 5mV1µsDIFFERENTIAL CONTROL INPUTS (DATA , NDATA , RCV , NRCV )Input High VoltageVIHInput Low VoltageDifferential Input Voltage-1.6 3.5VVIL-2.0 3.1VVDIFF 0.15 1.0V96104ΩMAX996 GCCQ, MAX996 JCCQ,between signal and complementInput ResistorSINGLE-ENDED CONTROL INPUTS (CS, RST, SCLK, DIN)Input High VoltageVIH1.63.5VInput Low VoltageVIL-0.1 0.9V50MHzSERIAL INTERFACE TIMING (Figure 5)SCLK FrequencyfSCLKSCLK Pulse Width HightCH8nsSCLK Pulse Width LowtCL8nstCSS03.5nsCS High to SCLK High SetuptCSS13.5nsSCLK High to CS High HoldtCSH13.5nstDS3.5nstDH3.5nstCSWH20nsCS Low to SCLK High SetupDIN to SCLK High SetupDIN to SCLK High HoldCS Pulse Width HighTEMPERATURE MONITOR (TEMP)TJ 70 C, RL 10MΩNominal VoltageTemperature CoefficientOutput Resistance3.43V 10mV/ C15kΩDRIVERS (Note 8)DC OUTPUT CHARACTERISTICS (RL 10MΩ )DHV , DLV , DTV , Output OffsetVoltageDHV , DLV , DTV , GainDHV , DLV , DTV , OutputVoltage Temperature CoefficientLinearity ErrorVOSAVAt DUT with VDHV 3V,VDTV 1.5V, VDLV 0MAX996 BMeasured with VDHV , VDLV ,VDTV at 0 and 4.5VMAX996 BIncludes both gain and offset temperatureeffects0.96 100mV1.001V/V 75µV/ C0V VDUT 3V (Note 9) 5Full range (Notes 9, 10) 15mV3MAX9965/MAX9966ELECTRICAL CHARACTERISTICS (continued)
MAX9965/MAX9966Quad Low-Power, 500MbpsATE Driver/ComparatorELECTRICAL CHARACTERISTICS (continued)(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note 1)PARAMETERSYMBOLCONDITIONSMINTYPMAXUNITSDHV to DLV CrosstalkVDLV 0, VDHV 200mV, 6.5V 2mVDLV to DHV CrosstalkVDHV 5V, VDLV -1.5V, 4.8V 2mVDTV to DLV and DHVCrosstalkVDHV 3V, VDLV 0,VDTV -1.5V, 6.5V 2mVDHV to DTV CrosstalkVDTV 1.5V, VDLV 0, VDHV 1.6V, 3V 3mVDLV to DTV CrosstalkVDTV 1.5V, VDHV 3V, VDLV 0, 1.4V 3mVDHV , DLV , DTVDC Power-Supply Rejection RatioVCC and VEE independently set to theirmin/max valuesPSRRdB 60Maximum DC Drive CurrentIDUTDC Output ResistanceRDUTIDUT 30mA (Note 11)ΔRDUTIDUT 1.0mA to 40mADC Output Resistance Variation4049 120mA5051Ω12.5ΩDYNAMIC OUTPUT CHARACTERISTICS (ZL 50Ω)Drive Mode OvershootVDLV 0, VDHV 0.1V30VDLV 0, VDHV 1V40VDLV 0, VDHV 3V50mVTerm Mode Overshoot(Note 12)0mVSettling Time to Within 25mV3V step (Note 13)10nsSettling Time to Within 5mV3V step (Note 13)20nsTIMING CHARACTERISTICS (ZL 50Ω) (Note 14)Prop Delay, Data to OutputtPDD2Prop Delay Match, TLH vs. THL3VP-PProp Delay Match, Drivers WithinPackage(Note 15)Prop Delay TemperatureCoefficient2.75ns 50ps40ps 3ps/ CProp Delay Change vs.Pulse Width3VP-P, 40MHz, 2.5ns to 22.5ns pulse width,relative to 12.5ns pulse width 60psProp Delay Change vs.Common-Mode VoltageVDHV - VDLV 1V, VDHV 0 to 6V85psProp Delay, Drive to High-ZtPDDZVDHV 1.0V, VDLV -1.0V, VDTV 02.9nsProp Delay, High-Z to DrivetPDZDVDHV 1.0V, VDLV -1.0V, VDTV 02.9nsProp Delay, Drive to TermtPDDTVDHV 3V, VDLV 0, VDTV 1.5V2.3nsProp Delay, Term to DrivetPDTDVDHV 3V, VDLV 0, VDTV 1.5V2.0nsDYNAMIC PERFORMANCE (ZL 50Ω)0.2 VP-P, 20% to 80%Rise and Fall TimetR, tF4506707503 VP-P, 10% to 90%1.11.21.45 VP-P, 10% to 90%43301 VP-P, 10% to 90%2.0psns
Quad Low-Power, 500MbpsATE Driver/Comparator(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note 1)PARAMETERSYMBOLCONDITIONSMINTYPMAXUNITSSC1 0, SC0 1 Slew RatePercent of full speed (SC0 SC1 0),3VP-P, 20% to 80%75%SC1 1, SC0 0 Slew RatePercent of full speed (SC0 SC1 0),3VP-P, 20% to 80%50%SC1 1, SC0 1 Slew RatePercent of full speed (SC0 SC1 0),3VP-P, 20% to 80%25%Minimum Pulse Width (Note 16)0.2VP-P, VDHV 0.2V, VDLV 00.651VP-P, VDHV 1V, VDLV 01.03VP-P, VDHV 3V, VDLV 02.05VP-P, VDHV 5V, VDLV 0Data Rate (Note 17)Dynamic Crosstalkns2.90.2VP-P, VDHV 0.2V, VDLV 017001VP-P, VDHV 1V, VDLV 010003VP-P, VDHV 3V, VDLV 05005VP-P, VDHV 5V, VDLV 0350(Note 18)Mbps20mVP-PRise and Fall Time, Drive to TermVDHV 3V, VDLV 0, VDTV 1.5V,tDTR, tDTF10% to 90% (Note 19)1.6nsRise and Fall Time, Term to DrivetTDR, tTDFVDHV 3V, VDLV 0, VDTV 1.5V,10% to 90% (Note 19)0.7nsCOMPARATORSDC CHARACTERISTICSInput Voltage RangeVINDifferential Input VoltageVDIFFHysteresisVHYSTInput Offset VoltageVOS(Note 4)-1.5 8VDUT 1.5VCMRRMAX996 BLinearity ErrorPower-Supply Rejection RatioPSRRVDUT -1.5V, 6.5V (Note 20)mV 10050µV/ C55dBVDUT 1.5V (Note 9) 1 5 1 1050mV 50VDUT -1.5V and 6.5V (Note 9)VDUT -1.5V, 6.5V (Note 21)VV0Input Offset Voltage TemperatureCoefficientCommon-Mode Rejection Ratio 6.566mVdBAC CHARACTERISTICS (Note 22)Minimum Pulse WidthProp DelaytPW(MIN)tPDLProp Delay TemperatureCoefficient(Note 23)MAX996 GCCQ0.6MAX996 HCCQ,MAX996 JCCQ0.91.22.6ns2.0nsps/ C5MAX9965/MAX9966ELECTRICAL CHARACTERISTICS (continued)
MAX9965/MAX9966Quad Low-Power, 500MbpsATE Driver/ComparatorELECTRICAL CHARACTERISTICS (continued)(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note 1)PARAMETERSYMBOLCONDITIONSMINProp Delay Match, High/Low vs.Low/HighProp Delay Match, ComparatorsWithin Package(Note 15)Prop Delay Dispersion vs.Common-Mode InputVCHV VCLV -1.4, 6.4V (Note 24)Prop Delay Dispersion vs.Overdrive50mV to 500mVProp Delay Dispersion vs. PulseWidth2.0ns to 23ns pulsewidth, relative to 12.5nspulse widthProp Delay Dispersion vs. SlewRate0.5V/ns to 6.5V/ns slew rate, peak-to-peakvariationWaveform Tracking 10% to 90%VDUT 1.0VP-P, tR tF 1.0ns 10% to 90%,relative to timing at 50%pointTYPMAXUNITS 40ps40ps 20ps60psMAX996 GCCQ 25MAX996 HCCQ,MAX996 JCCQ 45ps50Term mode50High-Z mode250pspsOPEN-COLLECTOR LOGIC OUTPUTS (CH , NCH , CL , NCL : MAX996 GCCQ)VCCO Voltage RangeVVCCOOutput Low Voltage Compliance0Set by IOUT, RTERM, and VCCO3.5-0.5VVOutput High VoltageVOHICH INCH ICL INCL 0VCCO VCCO- 0.1- 0.02VOutput Low VoltageVOLICH INCH ICL INCL 0VCCO- 0.4VOutput Voltage Swing0.350Single-ended measurement from VCCO toCH , NCH , CL , NCL0.380480.442V52ΩTermination ResistorRTERMDifferential Rise TimetR20% to 80%200psDifferential Fall TimetF20% to- 80%200psOPEN-EMITTER LOGIC OUTPUTS (CH , NCH , CL , NCL : MAX996 JCCQ)VCCO Voltage RangeVCCO Supply CurrentVCCOIVCCO-0.1All outputs 50Ω to(VVCCO - 2V)Output High VoltageVOH50Ω to (VVCCO - 2V)Output Low VoltageVOL50Ω to (VVCCO - 2V)Output Voltage Swing650Ω to (VVCCO - 2V)3.5330mAVCCO VCCO-1- 0.88VVCCO VCCO- 1.73- 1.5800850V950VmV
Quad Low-Power, 500MbpsATE Driver/Comparator(VCC 9.75V, VEE -5.25V, VCCO 2.5V, SC1 SC0 0, VCPHV 7.2V, VCPLV -2.2V, TJ 85 C, unless otherwise noted.All temperature coefficients are measured at TJ 60 C to 100 C, unless otherwise noted.) (Note ial Rise TimetR20% to 80%500psDifferential Fall TimetF20% to 80%500psCLAMPSHigh Clamp Input Voltage RangeVCPH-0.3 7.5VLow Clamp Input Voltage RangeVCPL-2.5 5.3VClamp Offset VoltageVOSAt DUT with IDUT 1mA, VCPHV 1.5V 100At DUT with IDUT -1mA, VCPLV 1.5V 100Offset Voltage TemperatureCoefficientClamp Power-Supply RejectionVoltage Gain 0.5PSRRVCC and VEE independently set to their minand max values, IDUT 1mA, VCPHV 040VCC and VEE independently set to their minand max values, IDUT -1mA, VCPLV 040AVShort-Circuit Output CurrentClamp DC ImpedancemV/ CdB0.96Voltage Gain TemperatureCoefficient1.00-100Clamp LinearityIDUTROUTmVIDUT 1mA, VCPLV -1.5V,VCPHV -0.3V to 6.5V 10IDUT -1mA, VCPHV 6.5V,VCPLV -1.5V to 5.3V 10V/Vppm/ CmVVCPHV 0, VCPLV -1.5V, VDUT 6.5V5095VCPLV 5V, VCPHV 6.5V, VDUT -1.5V-95-50VCPHV 3V, VCPLV 0,IDUT -5mA and -15mA5055VCPHV 3V, VCPLV 0,IDUT 5mA and 15mA5055mAΩNote 1: All min and max limits are 100% tested in production. Tests are performed at worst-case supply voltages where applicable.Note 2: Total for quad device at worst-case setting. RL 10MΩ. The applicable supply currents are measured with typical supplyvoltages.Note 3: Does not include internal dissipation of the comparator outputs. With output loads of 50Ω to (VVCCO - 2V), this adds240mW typical to the total chip power (MAX996 HCCQ, MAX996 JCCQ).Note 4: Provided that the Absolute Maximum Ratings are not exceeded, externally forced voltages may exceed this range.Note 5: Transition time from LLEAK being asserted to leakage current dropping below specified limits.Note 6: Transition time from LLEAK being deasserted to output returning to normal operating mode.Note 7: Based on simulation results only.Note 8: With the exception of Offset and Gain/CMRR tests, reference input values are calibrated for offset and gain.Note 9: Relative to straight line between 0 and 3V.Note 10: Full ranges are -1.3V VDHV 6.5V, -1.5V VDTV 6.5V, -1.5V VDLV 6.3V.Note 11: Nominal target value is 50Ω. Contact factory for alternate trim selections within the 40Ω to 50Ω range.Note 12: VDTV 1.5V, RS 50Ω. External signal driven into T-line is a 0 to 3V edge with 1.2ns rise time (10% to 90%).Measurement is made using the comparator.Note 13: Measured from the crossing point of DATA inputs to the settling of the driver output.7MAX9965/MAX9966ELECTRICAL CHARACTERISTICS (continued)
MAX9965/MAX9966Quad Low-Power, 500MbpsATE Driver/ComparatorNote 14: Prop delays are measured from the crossing point of the differential input signals to the 50% point of expected outputswing. Rise time of the differential inputs DATA and RCV is 250ps (10% to 90%).Note 15: Rising edge to rising edge or falling edge to falling edge.Note 16: Specified amplitude is programmed. At this pulse width, the output reaches at least 95% of its nominal (DC) amplitude.The pulse width is measured at DATA .Note 17: Specified amplitude is programmed. Maximum data rate specified in transitions per second. A square wave that reachesat least 95% of its programmed amplitude may be generated at one-half of this frequency.Note 18: Crosstalk from any driver to the other three channels. Aggressor channel is driving 3VP-P into a 50Ω load. Victim channelsare in term mode with VDTV 1.5V.Note 19: Indicative of switching speed from DHV or DLV to DTV and DTV to DHV or DLV when VDLV VDTV VDHV . IfVDTV VDLV or VDTV VDHV , switching speed is degraded by approximately a factor of 3.Note 20: Change in Offset Voltage over input range.Note 21: Change in Offset Voltage with power supplies independently set to their minimum and maximum values.Note 22: Unless otherwise noted, all Prop Delays are measured at 40MHz, VDUT 0 to 2V, VCHV VCLV 1V, slew rate 2V/ns,ZS 50Ω, driver in Term Mode with VDTV 0V. Comparator outputs are terminated with 50Ω to GND at scope input withVCCO 2V. Open-collector outputs are also terminated (internally or externally) with RTERM 50Ω to VCCO . Measuredfrom VDUT crossing calibrated CHV /CLV threshold to crossing point of differential outputs.Note 23: VDUT 0 to 1V, VCHV VCLV 0.5V. At this pulse width, the output reaches at least 90% of its DC Voltage swing. Thepulse width is measured at the crossing points of the differential outputs.Note 24: Relative to propagation delay at VCHV VCLV 1.5V. VDUT 200mVP-P. Overdrive 100mV.8
Quad Low-Power, 500MbpsATE Driver/ComparatorDLV 0VRL 50ΩDHV 5VDHV TO DTVV 0.25V/divDHV 3VV 500mV/divV 50mV/divDHV 200mVMAX9965 toc02DHV 500mVMAX9965 toc01DLV 0VRL 50ΩDRIVE TO TERM TRANSITIONDRIVER LARGE-SIGNAL RESPONSEMAX
MAX9965/MAX9966 Quad Low-Power, 500Mb
2015 suzuki king quad (lt-a400asi) tr 2016 suzuki king quad (lt-a400asi) tr 2017 suzuki king quad (lt-a400fsi) tr 2004 suzuki quad sport (lt-z400) tr 2005 suzuki quad sport (lt-z400) nt 2006 suzuki quad sport (lt-z400) nt 2007 suzuki quad sport (lt-z400) nt 2008 suzuki quad sport (lt-z400) nt 2009 suzuki quad
SUZUKI SUZUKI Years Hybrid SYSTEM #105590 SUZUKI 250 2x4 ‘97-01 N/D SUZUKI 280 King Quad ‘98 & Older N/D SUZUKI 300 King Quad ‘99-01 N/D SUZUKI 400 Eiger 2x4, 4x4 ‘02-07 N/D SUZUKI 400 King Quad 4x4/AS/AF/ASi/AFi ‘08-18 Yes SUZUKI 450 King Quad 4x4/AXi ‘07-10 Yes SUZUKI 500 King Quad AXI ‘09-18 Yes SUZ
the quad. William (Bill) Orr, W6SAI (SK) in his book "All About Cubical Quad Antennas" said a group of radio engineers installed a "gigantic" four element quad in Ecuador in 1939 (All About Cubical Quad Antennas, 2nd Ed., Radio Publications, Inc., 1977). Now I see various quad related designs (e.g. "Hexbeam", "Spiderbeam") that
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Which statement describes the fraction of a pizza that one of the friends ate? 1 2. F. Diego ate of a pizza, because he ate the largest piece of his 2 pieces. 1 3. G. Victoria ate of a pizza, because she ate 1 piece and had 3 equal-size pieces left over. 1 2. H. . 158: 175: What was the total number of tickets the theater sold for these three .
Single/Dual/Quad, Low Offset, Low Noise, RRO Operational Amplifiers General Description The LMV771/LMV772/LMV774 are Single, Dual, and Quad low noise precision operational amplifiers intended for use in a wide range of applications. Other important characteristics of
The UT54LVDS032LV Quad Receiver is a quad CMOS differential line receiver designed for applications requiring ultra low power dissipation and high data rates. The device is designed to support data rates in excess of 400.0 Mbps (200 MHz) utilizing Low
INSTRUMENTATION ENGINEERING For mechanical, instrumentation, electrical, and concrete data, a simple trend line produced a reasonable average. Correlating hours to the total mechanical equipment count did not produce a convergence (table 2, Mechanical 1). Mechanical 2 shows improvement to the correlation when the mechanical account was correlated separately to various equipment classes, pumps .
