SA05-11GWA, 规格书,Datasheet 资料

V IN-V IN+V OCMV S+V OUT+PDV S-V OUT-THS4502THS4503 SLOS352E–APRIL2002–REVISED OCTOBER2011 Wideband,Low-Distortion Fully Differential AmplifiersCheck for Samples:THS4502,THS4503FEATURES DESCRIPTIONThe THS4502and THS4503are high-performance •Fully Differential Architecturefully differential amplifiers from Texas Instruments.•Bandwidth:370MHz The THS4502,featuring power-down capability,and•Slew Rate:2800V/µs the THS4503,without power-down capability,set newperformance standards for fully differential amplifiers •IMD3:-95dBc at30MHzwith unsurpassed linearity,supporting14-bit •OIP3:51dBm at30MHzoperation through40MHz.Package options include •Output Common-Mode Control the8-pin SOIC and the8-pin MSOP withPowerPAD™for a smaller footprint,enhanced ac •Wide Power Supply Voltage Range:5V,±5V,performance,and improved thermal dissipation 12V,15Vcapability.•Centered Input Common-Mode Range•Power-Down Capability(THS4502)•Evaluation Module AvailableAPPLICATIONS•High Linearity Analog-to-Digital ConverterPreamplifier•Wireless Communication Receiver ChainsRELATED DEVICES•Single-Ended to Differential ConversionDEVICE(1)DESCRIPTION •Differential Line DriverTHS4500/1370MHz,2800V/µs,V ICR Includes V S–•Active Filtering of Differential SignalsTHS4502/3370MHz,2800V/µs,Centered V ICRTHS4120/1 3.3V,100MHz,43V/µs,3.7nV√HzTHS4130/1±15V,150MHz,51V/µs,1.3nV√HzTHS4140/1±15V,160MHz,450V/µs,6.5nV√HzTHS4150/1±15V,150MHz,650V/µs,7.6nV√Hz(1)Even numbered devices feature power-down capability.WARNINGThe THS4502and THS4503may have low-level oscillation when the dietemperature(also known as the junction temperature)exceeds+60°C.Thesedevices are not recommended for new designs where the die temperature isexpected to exceed+60°C.For more information,see Maximum Die Temperatureto Prevent Oscillation section.Please be aware that an important notice concerning availability,standard warranty,and use in critical applications of TexasInstruments semiconductor products and disclaimers thereto appears at the end of this data sheet.PowerPAD is a trademark of Texas Instruments.PRODUCTION DATA information is current as of publication date.Copyright©2002–2011,Texas Instruments Incorporated Products conform to specifications per the terms of the Texasf - Frequency - MHz-80-920204060- T h i r d -O r d e r I n t e r m o d u l a t i o n D i s t o r t i o n - d B c-74THIRD-ORDER INTERMODULATIONDISTORTION-6280100-68-86-9812101416I M D 3B i t sVTHS4502THS4503SLOS352E –APRIL 2002–REVISED OCTOBER 2011This integrated circuit can be damaged by ESD.Texas Instruments recommends that all integrated circuits be handled with appropriate precautions.Failure to observe proper handling and installation procedures can cause damage.ESD damage can range from subtle performance degradation to complete device failure.Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.PACKAGE/ORDERING INFORMATIONORDERABLE PACKAGE AND NUMBERPLASTIC MSOP (1)TEMPERATUREPLASTIC SMALL OUTLINEPLASTIC MSOP PowerPAD (D)(DGN)SYMBOL (DGK)SYMBOL THS4502CD THS4502CDGN BCG THS4502CDGK ATX 0°C to 70°C THS4503CD THS4503CDGN BCK THS4503CDGK ATY THS4502ID THS4502IDGN BCI THS4502IDGK ASX -40°C to 85°C THS4503IDTHS4503IDGNBCLTHS4503IDGKASY(1)All packages are available taped and reeled.The R suffix standard quatity is 2500.The T suffix standard quantity is 250(e.g.,THS4502DT).PIN ASSIGNMENTS2Submit Documentation Feedback Copyright ©2002–2011,Texas Instruments IncorporatedTHS4502THS4503 SLOS352E–APRIL2002–REVISED OCTOBER2011 ABSOLUTE MAXIMUM RATINGSover operating free-air temperature range unless otherwise noted(1)UNITSupply voltage,V S16.5VInput voltage,V I±V SOutput current,I O(2)150mADifferential input voltage,V ID4VContinuous power dissipation See Dissipation Rating Table Maximum junction temperature,T J(3)150°CMaximum junction temperature,continuous operation,long term reliability,T J(4)125°CMaximum junction temperature to prevent oscillation,T J(5)60°CC suffix0°C to70°COperating free-air temperature range,T AI suffix-40°C to85°CStorage temperature range,T stg-65°C to150°C(1)Stresses above these ratings may cause permanent damage.Exposure to absolute maximum conditions for extended periods maydegrade device reliability.These are stress ratings only,and functional operation of the device at these or any other conditions beyond those specified is not implied.(2)The THS450x may incorporate a PowerPAD on the underside of the chip.This acts as a heatsink and must be connected to a thermallydissipative plane for proper power dissipation.Failure to do so may result in exceeding the maximum junction temperature which could permanently damage the device.See TI technical brief SLMA002for more information about utilizing the PowerPAD thermally enhanced package.(3)The absolute maximum temperature under any condition is limited by the constraints of the silicon process.(4)The maximum junction temperature for continuous operation is limited by package constraints.Operation above this temperature mayresult in reduced reliability and/or lifetime of the device.(5)See Maximum Die Temperature to Prevent Oscillation section in the Application Information of this data sheet.PACKAGE DISSIPATION RATINGSθJCθJA(1)PACKAGE(°C/W)(°C/W)D(8pin)38.397.5DGN(8pin) 4.758.4DGK(8pin)54.2260(1)This data was taken using the JEDEC standard High-K test PCB.RECOMMENDED OPERATING CONDITIONSMIN NOM MAX UNITDual supply±5±7.5Supply voltage VSingle supply 4.5515C suffix070 Operating free-air temperature,T A°CI suffix-4085 Copyright©2002–2011,Texas Instruments Incorporated Submit Documentation Feedback3THS4502THS4503SLOS352E–APRIL2002–REVISED ELECTRICAL CHARACTERISTICS V S=±5VR f=R g=499Ω,R L=800Ω,G=+1,Single-ended input unless otherwise noted.THS4502AND THS4503TYP OVER TEMPERATURE(1)MIN/ PARAMETER TEST CONDITIONSTYP/0°C to-40°C to25°C25°C UNITS MAX70°C85°CAC PERFORMANCEG=+1,P IN=-20dBm,R f=392Ω370MHz TypG=+2,P IN=-30dBm,R f=1kΩ175MHz Typ Small-signal bandwidthG=+5,P IN=-30dBm,R f=1.3kΩ70MHz TypG=+10,P IN=-30dBm,R f=1.3kΩ30MHz Typ Gain-bandwidth product G>+10300MHz Typ Bandwidth for0.1dB flatness P IN=-20dBm150MHz Typ Large-signal bandwidth V P=2V220MHz Typ Slew rate4V PP Step2800V/µs Typ Rise time2V PP Step0.8ns Typ Fall time2V PP Step0.6ns Typ Settling time to0.01%V O=4V PP8.3ns Typ Settling time to0.1%V O=4V PP 6.3ns Typ Harmonic distortion G=+1,V O=2V PP Typf=8MHz-83dBc Typ 2nd harmonicf=30MHz-74dBc Typf=8MHz-97dBc Typ 3rd harmonicf=30MHz-78dBc TypThird-order intermodulation V O=2V PP,f c=30MHz,R f=392Ω,-94dBc Typ distortion200kHz tone spacingf c=30MHz,R f=392Ω,Third-order output intercept point52dBm TypReferenced to50ΩInput voltage noise f>1MHz 6.8nV/√Hz Typ Input current noise f>100kHz 1.7pA/√Hz Typ Overdrive recovery time Overdrive=5.5V75ns Typ DC PERFORMANCEOpen-loop voltage gain55525050dB Min Input offset voltage-1-4/+2-5/+3-6/+4mV Max Average offset voltage drift±10±10µV/°C Typ Input bias current4 4.65 5.2µA Max Average bias current drift±10±10nA/°C Typ Input offset current0.5122µA Max Average offset current drift±40±40nA/°C Typ INPUTCommon-mode input range±4.0±3.7±3.4±3.4V Min Common-mode rejection ratio80747070dB Min Input impedance107||1Ω||pF Typ OUTPUTDifferential output voltage swing R L=1kΩ±8±7.6±7.4±7.4V Min Differential output current drive R L=20Ω120110100100mA Min Output balance error P IN=-20dBm,f=100kHz-58dB TypClosed-loop output impedancef=1MHz0.1ΩTyp (single-ended)(1)See Maximum Die Temperature to Prevent Oscillation section in the Application Information of this data sheet.4Submit Documentation Feedback Copyright©2002–2011,Texas Instruments IncorporatedTHS4502THS4503 SLOS352E–APRIL2002–REVISED OCTOBER2011 ELECTRICAL CHARACTERISTICS V S=±5V(continued)R f=R g=499Ω,R L=800Ω,G=+1,Single-ended input unless otherwise noted.THS4502AND THS4503TYP OVER TEMPERATURE(1)MIN/ PARAMETER TEST CONDITIONSTYP/0°C to-40°C to25°C25°C UNITS MAX70°C85°COUTPUT COMMON-MODE VOLTAGE CONTROLSmall-signal bandwidth R L=400Ω180MHz Typ Slew rate2V PP step87V/µs Typ Minimum gain10.980.980.98V/V Min Maximum gain1 1.02 1.02 1.02V/V Max Common-mode offset voltage+2-1.6/+6.8-3.6/+8.8-4.6/+9.8mV Max Input bias current V OCM=2.5V100150170170µA Max Input voltage range±4±3.7±3.4±3.4V Min Input impedance25||1kΩ||pF Typ Maximum default voltage V OCM left floating00.050.100.10V Max Minimum default voltage V OCM left floating0-0.05-0.10-0.10V Min POWER SUPPLYSpecified operating voltage±5±8.25±8.25±8.25V Max Maximum quiescent current23283234mA Max Minimum quiescent current23181412mA Min Power supply rejection(±PSRR)80767370dB Min POWER DOWN(THS4502ONLY)Enable voltage threshold Device enabled ON above-2.9V-2.9V Min Disable voltage threshold Device disabled OFF below-4.3V-4.3V Max Power-down quiescent current800100012001200µA Max Input bias current200240260260µA Max Input impedance50||1kΩ||pF Typ Turnon time delay1000ns Typ Turnoff time delay800ns Typ ELECTRICAL CHARACTERISTICS V S=5VR f=R g=499Ω,R L=800Ω,G=+1,Single-ended input unless otherwise noted.THS4502AND THS4503TYP OVER TEMPERATURE(1)MIN/T PARAMETER TEST CONDITIONSYP/M0°C to-40°C to25°C25°C UNITS AX70°C85°CAC PERFORMANCEG=+1,P IN=-20dBm,R f=392Ω320MHz TypG=+2,P IN=-30dBm,R f=1kΩ160MHz Typ Small-signal bandwidthG=+5,P IN=-30dBm,R f=1.3kΩ60MHz TypG=+10,P IN=-30dBm,R f=1.3kΩ30MHz Typ Gain-bandwidth product G>+10300MHz Typ Bandwidth for0.1dB flatness P IN=-20dBm180MHz Typ Large-signal bandwidth V P=1V200MHz Typ Slew rate2V PP Step1300V/µs Typ Rise time2V PP Step0.6ns Typ Fall time2V PP Step0.8ns Typ Settling time to0.01%V O=2V Step13.1ns Typ (1)See Maximum Die Temperature to Prevent Oscillation section in the Application Information of this data sheet.Copyright©2002–2011,Texas Instruments Incorporated Submit Documentation Feedback5THS4502THS4503SLOS352E–APRIL2002–REVISED ELECTRICAL CHARACTERISTICS V S=5V(continued)R f=R g=499Ω,R L=800Ω,G=+1,Single-ended input unless otherwise noted.THS4502AND THS4503TYP OVER TEMPERATURE(1)MIN/T PARAMETER TEST CONDITIONSYP/M0°C to-40°C to25°C25°C UNITS AX70°C85°CSettling time to0.1%V O=2V Step8.3ns Typ Harmonic distortion V O=2V PP Typf=8MHz,-81dBc Typ 2nd harmonicf=30MHz-60dBc Typf=8MHz-74dBc Typ 3rd harmonicf=30MHz-62dBc Typ Input voltage noise f>1MHz 6.8nV/√Hz Typ Input current noise f>100kHz 1.6pA/√Hz Typ Overdrive recovery time Overdrive=5.5V75ns Typ DC PERFORMANCEOpen-loop voltage gain54514949dB Min Input offset voltage-0.6-3.6/+2.4-4.6/+3.4-5.6/+4.4mV Max Average offset voltage drift±10±10µV/°C Typ Input bias current4 4.65 5.2µA Max Average bias current drift±10±10nA/°C Typ Input offset current0.50.7 1.2 1.2µA Max Average offset current drift±20±20nA/°C Typ INPUTCommon-mode input range1/4 1.3/3.7 1.6/3.4 1.6/3.4V Min Common-mode rejection ratio80747070dB Min Input Impedance107||1Ω||pF Typ OUTPUTDifferential output voltage swing R L=1kΩ,Referenced to2.5V±3.3±2.8±2.6±2.6V Min Output current drive R L=20Ω100908080mA Min Output balance error P IN=-20dBm,f=100kHz-58dB TypClosed-loop output impedancef=1MHz0.1ΩTyp (single-ended)OUTPUT COMMON-MODE VOLTAGE CONTROLSmall-signal bandwidth R L=400Ω180MHz Typ Slew rate2V PP Step80V/µs Typ Minimum gain10.980.980.98V/V Min Maximum gain1 1.02 1.02 1.02V/V Max Common-mode offset voltage2-2.2/6.2-4.2/8.2-5.2/9.2mV Max Input bias current V OCM=2.5V1233µA Max Input voltage range1/4 1.2/3.8 1.3/3.7 1.3/3.7V Min Input impedance25||1kΩ||pF Typ Maximum default voltage V OCM left floating 2.5 2.55 2.6 2.6V Max Minimum default voltage V OCM left floating 2.5 2.45 2.4 2.4V Min POWER SUPPLYSpecified operating voltage516.516.516.5V Max Maximum quiescent current20252931mA Max Minimum quiescent current20161210mA Min Power supply rejection(+PSRR)75726966dB Min6Submit Documentation Feedback Copyright©2002–2011,Texas Instruments IncorporatedTHS4502THS4503 SLOS352E–APRIL2002–REVISED OCTOBER2011 ELECTRICAL CHARACTERISTICS V S=5V(continued)R f=R g=499Ω,R L=800Ω,G=+1,Single-ended input unless otherwise noted.THS4502AND THS4503TYP OVER TEMPERATURE(1)MIN/T PARAMETER TEST CONDITIONSYP/M0°C to-40°C to25°C25°C UNITS AX70°C85°CPOWER DOWN(THS4502ONLY)Enable voltage threshold Device enabled ON above2.1V 2.1V Min Disable voltage threshold Device disabled OFF below0.7V0.7V Max Power-down quiescent current60080012001200µA Max Input bias current100125140140µA Max Input impedance50||1kΩ||pF Typ Turnon time delay1000ns Typ Turnoff time delay800ns TypCopyright©2002–2011,Texas Instruments Incorporated Submit Documentation Feedback7THS4502THS4503SLOS352E–APRIL2002–REVISED TYPICAL CHARACTERISTICSTable of Graphs(±5V)FIGURESmall signal unity gain frequency response1Small signal frequency response20.1dB gain flatness frequency response3Harmonic distortion(single-ended input to differential output)vs Frequency4,6,12,14 Harmonic distortion(differential input to differential output)vs Frequency5,7,13,15 Harmonic distortion(single-ended input to differential output)vs Output voltage swing8,10,16,18 Harmonic distortion(differential input to differential output)vs Output voltage swing9,11,17,19 Harmonic distortion(single-ended input to differential output)vs Load resistance20Harmonic distortion(differential input to differential output)vs Load resistance21Third order intermodulation distortion(single-ended input to differential output)vs Frequency22Third order output intercept point vs Frequency23Slew rate vs Differential output voltage step24Settling time25,26Large-signal transient response27Small-signal transient response28Overdrive recovery29,30Voltage and current noise vs Frequency31Rejection ratios vs Frequency32Rejection ratios vs Case temperature33Output balance error vs Frequency34Open-loop gain and phase vs Frequency35Open-loop gain vs Case temperature36Input bias and offset current vs Case temperature37Quiescent current vs Supply voltage38Input offset voltage vs Case temperature39Common-mode rejection ratio vs Input common-mode range40 Differential output current drive vs Case temperature41Harmonic distortion(single-ended and differential input to differential output)vs Output common-mode voltage42Small signal frequency response at V OCM43Output offset voltage at V OCM vs Output common-mode voltage44Quiescent current vs Power-down voltage45Turnon and turnoff delay times46Single-ended output impedance in power down vs Frequency47Power-down quiescent current vs Case temperature48Power-down quiescent current vs Supply voltage498Submit Documentation Feedback Copyright©2002–2011,Texas Instruments IncorporatedTHS4502THS4503 SLOS352E–APRIL2002–REVISED OCTOBER2011 Table of Graphs(5V)FIGURESmall signal unity gain frequency response50Small signal frequency response510.1dB gain flatness frequency response52Harmonic distortion(single-ended input to differential output)vs Frequency53,54,61,63 Harmonic distortion(differential input to differential output)vs Frequency55,56,62,64 Harmonic distortion(single-ended input to differential output)vs Output voltage swing57,58,65,67 Harmonic distortion(differential input to differential output)vs Output voltage swing59,60,66,68 Harmonic distortion(single-ended input to differential output)vs Load resistance69Harmonic distortion(differential input to differential output)vs Load resistance70Slew rate vs Differential output voltage step71Large-signal transient response72Small-signal transient response73Voltage and current noise vs Frequency74Rejection ratios vs Frequency75Rejection ratios vs Case temperature76Output balance error vs Frequency77Open-loop gain and phase vs Frequency78Open-loop gain vs Case temperature79Input bias and offset current vs Case temperature80Quiescent current vs Supply voltage81Input offset voltage vs Case temperature82Common-mode rejection ratio vs Input common-mode range83Output drive vs Case temperature84Harmonic distortion(single-ended and differential input)vs Output common-mode range85Small signal frequency response at V OCM86Output offset voltage vs Output common-mode voltage87Quiescent current vs Power-down voltage88Turnon and turnoff delay times89Single-ended output impedance in power down vs Frequency90Power-down quiescent current vs Case temperature91Power-down quiescent current vs Supply voltage92Copyright©2002–2011,Texas Instruments Incorporated Submit Documentation Feedback9-2024680.11101001000f - Frequency - MHzS m a l l S i g n a l G a i n - d BSMALL SIGNAL FREQUENCY RESPONSE-4-3.5-3-2.5-2-1.5-1-0.500.510.11101001000f - Frequency - MHzS m a l l S i g n a l U n i t y G a i n - d BSMALL SIGNAL UNITY GAIN FREQUENCY RESPONSE-0.5-0.4-0.3-0.2-0.100.11f - Frequency - MHz0.1 d B G a i n F l a t n e s s - d B0.1 dB GAIN FLATNESS FREQUENCY RESPONSE-100-90-80-70-60-50-40-30-20-1000.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - VTHS4502THS4503SLOS352E –APRIL 2002–REVISED OCTOBER 2011TYPICAL CHARACTERISTICS (±5V Graphs)Figure 1.Figure 2.Figure 3.Figure 4.Figure 5.Figure 6.Figure 7.Figure 8.Figure 9.10Submit Documentation Feedback Copyright ©2002–2011,Texas Instruments Incorporated-100-90-80-70-60-50-40-30-20-1000123456H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-1000123456H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-10012345678910H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - VFigure 10.Figure 11.Figure 12.Figure 13.Figure 14.Figure 15.Figure 16.Figure 17.Figure 18.-100-90-80-70-60-50-40-30-20-100012345678910H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V -100-90-80-70-60-50-40-30-20-1040080012001600H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsLOAD RESISTANCER L - Load Resistance - Ω-100-90-80-70-60-50-40-30-20-10H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsLOAD RESISTANCER L - Load Resistance - Ω5001000150020002500300000.51 1.52 2.53 3.54V O - Differential Output Voltage Step - VS R - S l e w R a t e - SLEW RATEvsDIFFERENTIAL OUTPUT VOLTAGE STEPsµV /-100-90-80-70-60-50T h i r d -O r d e r I n t e r m o d u l a t i o n D i s t o r t i o n - d B cTHIRD-ORDER INTERMODULATIONDISTORTIONvsFREQUENCY40302015102030405060T h i r d -O r d e r O u t p u t I n t e r s e p t P o i n t - d B m5055 f - Frequency - MHzTHIRD-ORDER OUTPUT INTERCEPTPOINT vsFREQUENCY607080901004535255101520t - Time - ns- O u t p u t V o l t a g e - VSETTLING TIMEV O-2.5-2-1.5-1-0.500.511.522.55t - Time - ns- O u t p u t V o l t a g e - VSETTLING TIMEV O-3-2-1-1000100200300400500t - Time - ns- O u t p u t V o l t a g e - VLARGE-SIGNAL TRANSIENT RESPONSEV O Figure 19.Figure 20.Figure 21.Figure 22.Figure 23.Figure 24.Figure 25.Figure 26.Figure 27.t - Time - µs0-1-400.10.20.30.40.50.6S i n g l e -E n d e d O u t p u t V o l t a g e - V12OVERDRIVE RECOVERY40.70.80.913-3-5-250-0.5-20.5121.5-1.5-2.5-12.5- I n p u t V o l t a g e - VVI -0.4-0.3-0.2-0.1-1000100200300400500t - Time - ns- O u t p u t V o l t a g e - VSMALL-SIGNAL TRANSIENT RESPONSEV O -6-4-2024600.10.20.30.40.50.60.70.80.91-3-2-10123t - Time - µsS i n g l e -E n d e d O u t p u t V o l t a g e - VOVERDRIVE RECOVERY-I n p u t V o l t a g e - V V IR e j e c t i o n R a t i o s - d BREJECTION RATIOSvsf - Frequency - MHzR e j e c t i o n R a t i o s - d BREJECTION RATIOSvsCASE TEMPERATURECase Temperature - °Cf - Frequency - kHz- V o l t a g e N o i s e -VOLTAGE AND CURRENT NOISEvsFREQUENCYn V /H zV n-70-60-50-40-30-20-10O u t p u t B a l a n c e E r r o r - d BOUTPUT BALANCE ERRORvsFREQUENCYf - Frequency - MHzO p e n -L o o p G a i n - d B OPEN-LOOP GAIN AND PHASEvsFREQUENCYf - Frequency - MHzP h a s e -°O p e n -L o o p G a i n - d BOPEN-LOOP GAINvsCASE TEMPERATURECase Temperature - °CFigure 28.Figure 29.Figure 30.Figure 31.Figure 32.Figure 33.Figure 34.Figure 35.Figure 36.- I n p u t B i a s C u r r e n t -INPUT BIAS AND OFFSET CURRENTvsCASE TEMPERATURECase Temperature - °C- I n p u t O f f s e t C u r r e n t -I I B A µI O S A µV S - Supply Voltage - ±VQ u i e s c e n t C u r r e n t - m AQUIESCENT CURRENTvsSUPPL Y VOLTAGE0.511.522.5-40-30-20-100102030405060708090Case Temperature - °C- I n p u t O f f s e t V o l t a g e - m VINPUT OFFSET VOLTAGEvsCASE TEMPERATUREV O S -150-100-50D i f f e r e n t i a l O u t p u t C u r r e n t D r i v e - m ADIFFERENTIAL OUTPUT CURRENT DRIVEvsCASE TEMPERATURECase Temperature - °C-10Input Common-Mode Voltage Range - V C M R R - C o m m o n -M o d e R e j e c t i o n R a t i o - d BCOMMON-MODE REJECTION RATIOvsINPUT COMMON-MODE RANGEV OC - Output Common-Mode Voltage - VH a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT COMMON-MODE VOLTAGE-3-2-10123SMALL SIGNAL FREQUENCY RESPONSEAT V OCMf - Frequency - MHzS m a l l S i g n a l F r e q u e n c y R e s p o n s e a t V O C M - dB-600-400-2000200400600V OC - Output Common-Mode Voltage - V- O u t p u t O f f s e t V o l t a g e a tOUTPUT OFFSET VOLTAGE AT V OCMvsOUTPUT COMMON-MODE VOLTAGEV O S V O C M - m V-50510********Power-Down Voltage - VQ u i e s c e n t C u r r e n t - m AQUIESCENT CURRENTvsPOWER-DOWN VOLTAGEFigure 37.Figure 38.Figure 39.Figure 40.Figure 41.Figure 42.Figure 43.Figure 44.Figure 45.-1-2-5-3-6-4t - Time - msP o w e r d o w n V o l t a g e S i g n a l - VTURNON AND TURNOFF DELAY TIMESQ u i e s c e n t C u r r e n t - m A-40-30-20-100102030405060708090P o w e r -D o w n Q u i e s c e n t C u r r e n t - m APOWER-DOWN QUIESCENT CURRENTvsCASE TEMPERATURECase Temperature - °C- S i n g l e -E n d e d O u t p u t I m p e d a n c e SINGLE-ENDED OUTPUT IMPEDANCEIN POWER DOWNvsFREQUENCYZ O f - Frequency - MHzi n P o w e r D o w n -Ω0.511.522.533.544.55V S - Supply Voltage - ±VP o w e r -D o w n Q u i e s c e n t C u r r e n t -POWER-DOWN QUIESCENT CURRENTvsSUPPL Y VOLTAGEAµFigure 46.Figure 47.Figure 48.Figure 49.-202468f - Frequency - MHzS m a l l S i g n a l G a i n - d BSMALL SIGNAL FREQUENCY RESPONSE-4-3-2-1010.11101001000f - Frequency - MHzS m a l l S i g n a l U n i t y G a i n - d BSMALL SIGNAL UNITY GAIN FREQUENCY RESPONSE-0.5-0.4-0.3-0.2-0.100.21101001000f - Frequency - MHz0.1 d B G a i n F l a t n e s s - d B0.1 dB GAIN FLATNESSFREQUENCY RESPONSE0.1-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - dB cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-100.1110100H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsFREQUENCYf - Frequency - MHz-100-90-80-70-60-50-40-30-20-1000.511.522.533.544.55H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - V-100-90-80-70-60-50-40-30-20-1000.511.522.533.544.55H a r m o n i c D i s t o r t i o n - d B cHARMONIC DISTORTIONvsOUTPUT VOLTAGE SWINGV O - Output Voltage Swing - VTYPICAL CHARACTERISTICS (5V GRAPHS)Figure 50.Figure 51.Figure 52.Figure 53.Figure 54.Figure 55.Figure 56.Figure 57.Figure 58.。

July 2008Rev 21/18STCS05A0.5 A max constant current LED driverFeatures■Up to 40 V input voltage■Less than 0.5 V voltage overhead ■Up to 0.5 A output current ■PWM dimming pin ■Shutdown pin■LED disconnection diagnostic ■Slope control with external capApplications■LED constant current supplying for varying input voltages ■Low voltage lighting■Small appliances LED lighting ■Car LED lightsDescriptionThe STCS05A is a BiCMOS constant current source designed to provide a precise constant current starting from a varying input voltage source. The main target is to replace discretecomponents solution for driving LEDs in low voltage applications such as 5 V , 12 V or 24 V giving benefits in terms of precision, integration and reliability.The current is set with external resistor up to 0.5 A with a ± 10 % precision; a dedicated pin allows implementing PWM dimming. An externalcapacitor allows setting the slope for the current rise from tens of microseconds to tens of milliseconds allowing reduction of EMI.An open-drain pin output provides information on load disconnection condition.SO-8Table 1.Device summaryOrder code Package Packaging STCS05ADRSO-82500 parts per reelContents STCS05AContents1Application diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2Pin configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 5Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 6Typical performance characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87Detail description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107.1Current setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107.2Enable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107.3PWM dimming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107.4Diagnostic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128.1Reverse polarity protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 128.2Thermal considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 9Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 10Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 172/18STCS05A Application diagram3/181 Application diagramPin configuration STCS05A4/182 Pin configurationTable 2.Pin descriptionPin n°Symbol Note1V CC Supply voltage 2PWM PWM dimming input 3EN Shutdown pin4DRAIN Internal N-MOSFET drain5FB Feedback input. The control loop regulates the current in such a way that the average voltage at the FB input is 100 mV (nominal). The cathode of the LED and a resistor to ground to set the LED current should be connected at this point.6GND Ground7SLOPE Capacitor for slope control8DISCLoad disconnection flag (open drain)STCS05A Maximum ratings5/183 Maximum ratingsNote:Absolute maximum ratings are those values beyond which damage to the device may occur.Functional operation under these conditions is not implied.Table 3.Absolute maximum ratingsSymbol ParameterValue Unit V CC DC supply voltage -0.3 to +45V DRAIN Drain pin -0.3 to +45PWM, EN, DISC Logic pins -0.3 to + V CC + 0.3V SLOPE, FBConfiguration pins-0.3 to + 3.3V ESD Human body model (all pins)±2kV Power DissipationSO-8 T A =25°C (1)1.See Figure 16 for details of max power dissipation for ambient temperature higher than 25 °C0.85W T J Junction temperature -40 to 150°C T STGStorage temperature range-55 to 150°CTable 4.Thermal dataSymbol ParameterSO-8Unit R thJC Thermal resistance junction-case 20°C/W R thJAThermal resistance junction-ambient (1)100°C/W1.This value depends from thermal design of PCB on which the device is mounted.Electrical characteristics STCS05A6/184 Electrical characteristicsNote:All devices 100 % production tested at T A = 25 °C. Limits over the operating temperature range are guaranteed by design.Table 5.Electrical characteristics (V CC = 12 V; I O = 100 mA; T J = -40 °C to 125 °C; V DRAIN = 1 V;C DRAIN = 1 µF; C BYP = 100 nF typical values are at T A = 25 °C, unless otherwise specified)Symbol ParameterTest conditionsMin.Typ.Max.Unit V CCSupply voltage range 4.540V Output current range1500mA I OOutput currentR FB = 0.2 Ω500mA Regulation (percentage with respect to V CC = 12 V)V CC = 4.5 to 40V ,I O = 100mA; V DRAIN = 1V -1+1%V FBFeedback VoltageI O = 0 to 0.5A 90100110mVI CCQuiescent current (Measured onV CC pin)On Mode450750µAShutdown Mode;V CC = 5 to 12V1Shutdown Mode;V CC = 12 to 40V 3V DROPDropout voltage (V DRAIN to GND)I O = 100mA 0.120.16V I O = 0.5A0.580.9LEAK DRAIN Drain leakage current Shutdown; V DRAIN = 40V 10µA T R /T FRise/Fall time of the current on PWM transitionC SLOPE = 10 nF ,T J = -40 °C to 105 °C 800µs T DDelay on PWM signal (see Figure 3)V PWM rising, V CC = 12V C SLOPE = floating, 3µsV PWM falling, V CC = 12V C SLOPE = floating 1.2DISCLow level voltageI SINK = 5mA 0.20.5V Leakage currentV DISC = 5V 1µA Load disconnection threshold (V DRAIN -GND)DISC Turn-ON 75mV DISC Turn-OFF110Thermal ProtectionShutdown temperature 155°CHysteresis25Logic inputs (PWM and EN)V L Input low level 0.4V V HInput high level1.2VEN, PWM leakage current V EN = 5V; V PWM = 5V 2µAEN input leakage current V EN = 40V 60PWM input leakage currentV PWM = 40V120STCS05A Timing 5 Timing7/188/186 Typical performance characteristicsFigure 7.I DRAIN vs temperature Figure 8.V DROP (including V FB) vstemperatureFigure 9.I CC vs temperature Figure 10.I CC vs V CC9/18Figure 13.Rise timeFigure 14.Fall timeI DRAIN = 80 mA -C SLOPE = 10nF -T A = 25°CV PWM 2V/DIV I DRAIN 20mA/DIV V DRAIN 1V/DIV Time 210µsec/DIVV PWM 2V/DIV I DRAIN 20mA/DIV V DRAIN 1V/DIV Time 200µsec/DIVI DRAIN = 80 mA -C SLOPE = 10nF -T A = 25°C V PWM 2V/DIV I DRAIN 20mA/DIV V DRAIN 1V/DIV Time 200µsec/DIVI DRAIN = 80 mA -C SLOPE = 10nF -T A = 25°CDetail description STCS05A10/187 Detail descriptionThe STCS05A is a BiCMOS constant current source designed to provide a precise constantcurrent starting from a varying input voltage source. The main target is to replace discrete components solution for driving LEDs in low voltage applications such as 5 V, 12 V or 24 V giving benefits in terms of precision, integration and reliability.7.1 Current settingThe current is set with an external sensing resistor connected to the FB pin. The feedbackvoltage is 100 mV, then a low resistor value can be chosen reducing power dissipation. A value between 1 mA and 500 mA can be set according to the resistor value, the resulting output current has a tolerance of ± 10 %.For instance, should one need a 350 mA LEDs current, R F should be selected according to the following equation:R F = V FB / I LEDs = 100 mV / 350 mA = 284 m Ω7.2 EnableWhen the enable pin is low the device completely off thus reducing current consumption to less than 1 µA. When in shutdown mode, the internal main switch is off.7.3 PWM dimmingThe PWM input allows implementing PWM dimming on the LED current; when the PWMinput is high the main switch will be on and vice versa. A typical frequency range for the input is from few Hertz to 50 kHz. The maximum dimming frequency is limited by theminimum rise/fall time of the current (obtained with C SLOPE = 0) which is around 4 µs each. Above 50 kHz the current waveforms starts assuming a triangular shape.While the PWM input is switching, the overall circuitry remains on, this is needed in order to implement two important features: short delay time and controlled slope for the current.Since the PWM pin is controlling just the main switch, the overall circuitry is always on and it is able to control the delay time between the PWM input signal and the output current in the range of few µs, this is important to implement synchronization among several light LED sources.The rise and fall slope of the current is controlled by the C SLOPE capacitor. The rise and fall time are linear dependent from the C SLOPE capacitor value (see graph in typicalcharacteristics). A controlled rise time has two main benefits: reducing EMI noise and avoid current spike at turn on.When C SLOPE is left floating, the internal switch is turned on at maximum speed, in this condition an overshoot can be present on the LED current before the system goes into regulation.分销商库存信息: STMSTCS05ADR。

硅酸盐连续测定仪操作手册COPRA SILICA96-251011ANALYTICAL INSTRUMENTSSwan Analytical Instruments AG CH-8616 Riedikon / Uster目录目录ⅰ警告及注意事项ii安装启动步骤iii 1.1 概述 1.11.2 工作原理 1.11.2.1 测量原理 1.11.2.2 在线操作 1.22 安装 2.12.1 安装要求 2.12.2 样水要求 2.12.3 拆箱 2.12.4 安装 2.22.5 接线 2.42.6 安装压力棒 2.112.7 启动 2.123 显示屏与键盘 3.1 3.1 显示屏 3.13.2 键盘 3.24 模式设置 4.14.1 串行接口 (RS232) 4.24.2 FIELDBUS/MODEM 4.34.3 打印输出 4.44.4 记录器 4.5 4.5 校准 4.64.6 测量参数 4.84.7 选项 4.104.8 维护 4.125 用户模式 5.15.1 手工取样 5.25.2 硅表的限位 5.35.3 打印机 5.4 5.4 记录器 5.7 5.5 系统 5.95.6 诊断 5.116 维护 6.16.1 维护时间表 6.16.2 更换泵管 6.26.3 配制试剂 6.5______________________________________________________________________________ ii6.4 清洗试剂过滤器 6.6 6.5 更换阴离子交换柱 6.66.6 电磁阀的维护 6.8 6.7 更换通道选择阀 6.9 6.8 维护之后的启动 6.11 6.9 测量中断/完全停运及拆卸仪器 6.11 6.10 错误信息 6.12______________________________________________________________________________ iii警告仪表符合DIN57411 part 1/VDE 041 part 1、“电子测量仪保护措施”，并且在无故障条件下出厂。

GW5（A ）—1265.725.40 型户外高压交流隔离开关安装使用说明书0RG.412.472.3江苏省如高高压电器有限公司年 月 日前 言本安装使用说明书适用于GW5（A ）—1265.725.40 型户外交流高压隔离开关。

本安装使用说明书作为GW5（A ）—1265.725.40 型户外交流高压隔离开关安装使用说明书印刷用。

本产品符合GB1985-2000《高压交流隔离开关和接地开关》和DL/T486 –2000《交流高压隔离开关和接地开关订货技术条件》有关规定。

本安装使用说明书主要起草人：屈荣。

安装使用说明书1概述主要用途GW5(A)系列户外高压交流高压隔离开关（以下简称隔离开关）是三相交流50Hz的户外高压电器，用于额定电压为35、66、110kV的电力系统中。

供高压线路在有电压无负载情况下进行切换，以及对被检修的高压母线，断路器等电气设备与带电的高压线路进行电气隔离，也可用于分合小的电容电流或电感电流。

产品特点a) 采用V型90°旋转传动方式，从而受力平衡稳定，操作轻巧可靠，结构简单合理；采用双柱中开，触头转入式结构，具有自清洁触头的能力，提高了接触可靠性。

导电回路采用矩形管，大大降低了主导电部分的温升。

b) 触指采用高强度、高导电率、高弹性的新型材料制造。

依靠触指自身弹力夹紧触头，避免了目前因弹簧锈蚀、发热退火而引起的触头夹紧力降低，接触电阻增加，触头发热加剧的恶性循环。

且触指与触指座采用螺栓固定连接，又避免了油污、灰尘进入其接触点，使接触电阻增加的可能性。

此导电部分结果已获国家实用新型专利。

c) 转动部分按照免维护的要求设计：转动座设计成密封结构，水汽、尘埃、有害气体无法进入，使轴承、润滑脂永远工作在良好的环境中，并采二硫化钼锂基润滑脂。

轴承永不生锈、润滑脂无法流失，永不干固；传动部分采用不锈钢轴销与无油自润滑轴承相配合结构；钢制件采用热镀锌工艺，确保隔离开关操作灵活、轻便、可靠、永不生锈。

Ra-01S规格书版本V1.1版权©2020免责申明和版权公告本文中的信息，包括供参考的URL地址，如有变更，恕不另行通知。

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本文档不负任何责任，包括使用本文档内信息产生的侵犯任何专利权行为的责任。

本文档在此未以禁止反言或其他方式授予任何知识产权使用许可，不管是明示许可还是暗示许可。

文中所得测试数据均为安信可实验室测试所得，实际结果可能略有差异。

文中提到的所有商标名称、商标和注册商标均属其各自所有者的财产，特此声明。

最终解释权归深圳市安信可科技有限公司所有。

注意由于产品版本升级或其他原因，本手册内容有可能变更。

深圳市安信可科技有限公司保留在没有任何通知或者提示的情况下对本手册的内容进行修改的权利。

本手册仅作为使用指导，深圳市安信可科技有限公司尽全力在本手册中提供准确的信息，但是深圳市安信可科技有限公司并不确保手册内容完全没有错误，本手册中的所有陈述、信息和建议也不构成任何明示或暗示的担保。

文件制定/修订/废止履历表版本日期制定/修订内容制定核准V1.02020.8.12首版徐V1.12020.8.19更新部分参数徐目录一、产品概述 (5)二、电气参数 (6)三、外观尺寸 (8)四、管脚定义 (10)五、原理图 (11)六、设计指导 (12)七、回流焊曲线图 (14)八、包装信息 (15)九、联系我们 (15)一、产品概述安信可LoRa系列模块（Ra-01S）由安信可科技设计开发。

该模组用于超长距离扩频通信，其射频芯片SX1268主要采用LoRa™远程调制解调器，用于超长距离扩频通信，抗干扰性强，能够最大限度降低电流消耗。

借助SEMTECH的LoRa™专利调制技术，SX1268具有超过-148dBm的高灵敏度，+22dBm的功率输出，传输距离远，可靠性高。

同时，相对传统调制技术，LoRa™调制技术在抗阻塞和选择方面也具有明显优势，解决了传统设计方案无法同时兼顾距离、抗干扰和功耗的问题。

5 WattSingle/Dual Output●AC-DC Power Supply●5 Watt PCB Mount Package ●Universal Input Voltage Range ●3000VAC Isolation●Low Output Ripple and Noise ●Short Circuit Protected ●UL Approved, CE MarkedFeaturesRegulated ConvertersSelection GuidePart Input Output Output Efficiency Max Number Range Voltage Current Capacitive (VAC)(VDC)(mA)(%)Load RAC05-3.3SA 90-264 3.315006240000µF RAC05-05SA 90-264510006519000µF RAC05-12SA 90-26412416704000µF RAC05-15SA 90-26415333703500µF RAC05-24SA 90-2642420071900µF RAC05-05DA 90-264±5±50070±9500µF RAC05-12DA 90-264±12±20067±1400µF RAC05-15DA90-264±15±16067±950µF*add suffix “-E” for extended temperature range, e.g. RAC05-05SA-E*add suffix "-ST” for screw terminal module e.g. RAC05-05SA-ST, RAC05-05DA-E-STInput Voltage Range 90-264VAC or 120-370VDCRated Power5 Watts maxInput Frequency Range (for AC Input)47-440HzInput Current (full load)115VAC/230VAC 120mA /70mA max.No Load Power Consumption 115VAC/230VAC 1.18W max.Inrush Current (<2ms)115VAC 10A max. (-E = 23A max.)230VAC20A max. (-E = 46A max.)Leakage Current0.75mA maxOutput Voltage Accuracy (full load)±2%Line Voltage Regulation (low line, high line at full load)±0.3% typ Load Voltage Regulation ( 5% to 100% full load )±0.5% typOutput Ripple and Noise (20MHz limited)Ripple <0.2% Vout + 40mVp-p max Noise0.5% Vout + 50mVp-p maxOperating Frequency 100kHz typ Efficiency at full Loadsee table RMS Isolation Voltage (input to output)3kVAC / 1minute Temperature Coefficient ±0.02%/°C typ Isolation Resistance 100 M ΩmaxShort Circuit Protection Hiccup, Automatic RestartOperating Temperature Range Standard -25°C to +70°C (free air convection, with derating)Suffix -E -40°C to +70°C Storage Temperature Range -40°C to +85°C Humidity 95% RH maxCase Material Epoxy with Fibreglass (UL94V-0)Package Weight 80gPacking Quantity 5 pcs (-ST Version: 1 pc)EMC EN 55022 ClassB / EN 50082-1MTBF (+25°C)using MIL-HDBK-217F300 x 103hoursDerating Graph(Ambient T emperature)DescriptionSpecifications (typical at 25°C and after warm up time unless otherwise specified )Compact UL certified switching AC/DC power module for PCB, screw-terminal connection or DIN-rail mounting.UL-60950-1 CertifiedRAC05-APOWERLINEAC/DC-Converterwith 3 year WarrantyPlease Read Application Notes R A C 05-AREV: 1/2011PA-10RoHS2002/95/EC6/6E196683/RAC05-S_DA SeriesPOWERLINEAC/DC-ConverterStandard Package Style and PinningScrew Terminal Module Option (suffix -ST)XX.X ± 0.5 mm XX.XX ± 0.25 mmPin Connections-Pin #Single Out Dual Out 1FG FG 2VAC in (N)VAC in (N)3VAC in (L)VAC in (L)4-VDC out -VDC out 5No Pin Com 6+VDC out+VDC outREV:1/2011PA-11 RAC05-AStandard Application CircuitSuggested fuse rating 1A Slow Blow3rd angle projection/分销商库存信息:RECOM-POWERRAC05-05SA RAC05-12SA RAC05-15SA RAC05-24SA RAC05-3.3SA RAC05-05DA RAC05-12DA RAC05-15DA RAC05-05DA-E RAC05-12DA-E RAC05-15DA-E RAC05-05SA-E RAC05-12SA-E RAC05-15SA-E RAC05-24SA-E RAC05-3.3SA-E RAC05-05SA-ST RAC05-12SA-ST RAC05-15SA-ST RAC05-24SA-ST RAC05-3.3SA-ST RAC05-05DA-ST RAC05-12DA-ST RAC05-15DA-ST RAC05-05SA-E-ST RAC05-12SA-E-ST RAC05-15SA-E-ST RAC05-24SA-E-ST RAC05-3.3SA-E-ST。

6.1 6.0 5.02012-06-272012-04-302007-01-25SStSStSMuSStSMu-Würth Elektronik eiSos GmbH & Co. KGEMC & Inductive SolutionsMax-Eyth-Str. 174638 WaldenburgGermanyTel. +49 (0) 79 42 945 - 0A Dimensions: [mm]Additional FeaturesSafety key to lock/ unkock74271D2 General Properties:Ferrite core Ferrite core Ferrite core Plastic housing Plastic housing Test cable Test cablePropertiesMaterial Initial permeability Curie temperatureColourFlammability ClassificationApplicable cable Applicable cable lengthµi T CValue 4 W 620620150Grey UL94-V0AWG26120Unit°Cmm Tol.typ.typ.F Typical Impedance Characteristics:I Cautions and Warnings:The following conditions apply to all goods within the product series of WE-STAR RINGof Würth Elektronik eiSos GmbH & Co. KG:General:All recommendations according to the general technical specifications of the data sheet have to be complied with.The disposal and operation of the product within ambient conditions which probably alloy or harm the component surface has to be avoided.The packaging of the product is to encase the needed humidity of the plastic housing. To ensure the humidity level, the products have to be stored in this delivered packaging. If not, the products are losing their humidity. In this case you can re-condition the components according to the internal standard WE1883 to ensure the necessary humidity in the plastic.To ensure the operating mode of the product, the ambient temperature at processing (when the part will be mounted on the cable) has to be in the range of 15 to 25 °C.Before mounting, the part should be stored for one hour in this condition.The responsibility for the applicability of customer specific products and the use in a particular customer design is always within the authority of the customer. All technical specifications for standard products do also apply for customer specific products.Direct mechanical impact to the product and the forcible closing of this shall be prevented as the ferrite material of the ferrite body or the pla-stic housing could flake or in the worst case it could break.Product specific:Follow all instructions mentioned in the datasheet, especially:•The cable diameter must be pointed out, otherwise no warranty will be sustained.•Violation of the technical product specifications such as exceeding the nominal rated current will result in the loss of warranty.1. General Customer ResponsibilitySome goods within the product range of Würth Elektronik eiSos GmbH & Co. KG contain statements regarding general suitability for certain application areas. These statements about suitability are based on our knowledge and experience of typical requirements concerning the are-as, serve as general guidance and cannot be estimated as binding statements about the suitability for a customer application. The responsibi-lity for the applicability and use in a particular customer design is always solely within the authority of the customer. Due to this fact it is up to the customer to evaluate, where appropriate to investigate and decide whether the device with the specific product characteristics described in the product specification is valid and suitable for the respective customer application or not.2. Customer Responsibility related to Specific, in particular Safety-Relevant ApplicationsIt has to be clearly pointed out that the possibility of a malfunction of electronic components or failure before the end of the usual lifetime can-not be completely eliminated in the current state of the art, even if the products are operated within the range of the specifications.In certain customer applications requiring a very high level of safety and especially in customer applications in which the malfunction or failure of an electronic component could endanger human life or health it must be ensured by most advanced technological aid of suitable design of the customer application that no injury or damage is caused to third parties in the event of malfunction or failure of an electronic component.3. Best Care and AttentionAny product-specific notes, warnings and cautions must be strictly observed.4. Customer Support for Product SpecificationsSome products within the product range may contain substances which are subject to restrictions in certain jurisdictions in order to serve spe-cific technical requirements. Necessary information is available on request. In this case the field sales engineer or the internal sales person in charge should be contacted who will be happy to support in this matter.5. Product R&DDue to constant product improvement product specifications may change from time to time. As a standard reporting procedure of the Product Change Notification (PCN) according to the JEDEC-Standard inform about minor and major changes. In case of further queries regarding the PCN, the field sales engineer or the internal sales person in charge should be contacted. The basic responsibility of the customer as per Secti-on 1 and 2 remains unaffected.6. Product Life CycleDue to technical progress and economical evaluation we also reserve the right to discontinue production and delivery of products. As a stan-dard reporting procedure of the Product Termination Notification (PTN) according to the JEDEC-Standard we will inform at an early stage about inevitable product discontinuance. According to this we cannot guarantee that all products within our product range will always be available. Therefore it needs to be verified with the field sales engineer or the internal sales person in charge about the current product availability ex-pectancy before or when the product for application design-in disposal is considered.The approach named above does not apply in the case of individual agreements deviating from the foregoing for customer-specific products.7. Property RightsAll the rights for contractual products produced by Würth Elektronik eiSos GmbH & Co. KG on the basis of ideas, development contracts as well as models or templates that are subject to copyright, patent or commercial protection supplied to the customer will remain with Würth Elektronik eiSos GmbH & Co. KG.8. General Terms and ConditionsUnless otherwise agreed in individual contracts, all orders are subject to the current version of the “General Terms and Conditions of Würth Elektronik eiSos Group”, last version available at .J Important Notes:The following conditions apply to all goods within the product range of Würth Elektronik eiSos GmbH & Co. KG:分销商库存信息: WURTH-ELECTRONICS 7427155。

1 General DescriptionThe AS5045 is a contactless magnetic rotary encoder for accurate angular measurement over a full turn of 360°. It is a system-on-chip, combining integrated Hall elements, analog front end and digital signal processing in a single device.To measure the angle, only a simple two-pole magnet, rotating over the center of the chip, is required. The magnet may be placed above or below the IC.The absolute angle measurement provides instant indication of the magnet’s angular position with a resolution of 0.0879° = 4096 positions per revolution. This digital data is available as a serial bit stream and as a PWM signal.An internal voltage regulator allows the AS5045 to operate at either 3.3 V or 5 V supplies.2 BenefitsComplete system-on-chipFlexible system solution provides absolute andPWM outputs simultaneously Ideal for applications in harsh environments due tocontactless position sensing No calibration required3 Key FeaturesContactless high resolution rotational positionencoding over a full turn of 360 degrees Two digital 12bit absolute outputs:- Serial interface and- Pulse width modulated (PWM) output User programmable zero positionFailure detection mode for magnet placementmonitoring and loss of power supply “red-yellow-green” indicators display placement ofmagnet in Z-axis Serial read-out of multiple interconnected AS5045devices using Daisy Chain mode Tolerant to magnet misalignment and airgapvariations Wide temperature range: - 40°C to + 125°CSmall Pb-free package: SSOP 16 (5.3mm x 6.2mm)4 ApplicationsIndustrial applications:- Contactless rotary position sensing - Robotics Automotive applications:- Steering wheel position sensing - Transmission gearbox encoder - Headlight position control - Torque sensing- Valve position sensing Replacement of high end potentiometersFigure 1. Typical Arrangement of AS5045 and MagnetAS504512 Bit Programmable Magnetic Rotary Encoder Data SheetTable of Contents1General Description (1)2Benefits (1)3Key Features (1)4Applications (1)5Pinout (4)5.1Pin Configuration (4)5.2Pin Description (4)6Electrical Characteristics (5)6.1AS5045 Differences to AS5040 (5)6.2Absolute Maximum Ratings (non operating) (6)6.3Operating Conditions (6)6.4DC Characteristics for Digital Inputs and Outputs (7)6.4.1CMOS Schmitt-Trigger Inputs: CLK, CSn. (CSn = internal Pull-up) (7)6.4.2CMOS / Program Input: Prog (7)6.4.3CMOS Output Open Drain: MagINCn, MagDECn (7)6.4.4CMOS Output: PWM (7)6.4.5Tristate CMOS Output: DO (8)6.5Magnetic Input Specification (8)6.6Electrical System Specifications (9)6.7Timing Characteristics (10)6.7.1Synchronous Serial Interface (SSI) (10)6.7.2Pulse Width Modulation Output (11)6.8Programming Conditions (11)7Functional Description (12)8Mode Input Pin (13)8.1Synchronous Serial Interface (SSI) (13)8.1.1Data Content (14)8.1.2Z-axis Range Indication (Push Button Feature, Red/Yellow/Green Indicator) (14)8.2Daisy Chain Mode (15)9Pulse Width Modulation (PWM) Output (16)9.1Changing the PWM Frequency (17)10Analog Output (17)11Programming the AS5045 (18)11.1Zero Position Programming (18)11.2Repeated OTP Programming (18)11.3Non-permanent Programming (19)11.4Analog Readback Mode (20)12Alignment Mode (21)13 3.3V / 5V Operation (22)14Choosing the Proper Magnet (23)14.1Physical Placement of the Magnet (24)15Simulation Modeling (25)16Failure Diagnostics (26)16.1Magnetic Field Strength Diagnosis (26)16.2Power Supply Failure Detection (26)17Angular Output Tolerances (26)17.1Accuracy (26)17.2Transition Noise (28)17.3High Speed Operation (28)17.3.1Sampling Rate (28)17.4Propagation Delays (29)17.4.1Angular Error Caused by Propagation Delay (29)17.5Internal Timing Tolerance (29)17.6Temperature (30)17.6.1Magnetic Temperature Coefficient (30)17.7Accuracy over Temperature (30)17.7.1Timing Tolerance over Temperature (30)18Package Drawings and Markings (31)19Ordering Information (31)20Recommended PCB Footprint (32)5 Pinout5.1 Pin ConfigurationFigure 2. Pin Configuration SSOP165.2 Pin DescriptionTable 1 shows the description of each pin of the standard SSOP16 package (Shrink Small Outline Package, 16 leads, body size: 5.3mm x 6.2mmm; see Figure 2).Pins 7, 15 and 16 supply pins, pins 3, 4, 5, 6, 13 and 14 are for internal use and must not be connected.Pins 1 and 2 MagINCn and MagDECn are the magnetic field change indicators (magnetic field strength increase or decrease through variation of the distance between the magnet and the device). These outputs can be used to detect the valid magnetic field range. Furthermore those indicators can also be used for contact-less push-button functionality.Pin 6 Mode allows switching between filtered (slow) and unfiltered (fast mode). This pin must be tied to VSS or VDD5V, and must not be switched after power up. See chapter 8 Mode Input Pin.Pin 8 Prog is used to program the zero-position into the OTP (see chapter 11.1 Zero Position Programming).This pin is also used as digital input to shift serial data through the device in Daisy Chain configuration, (see chapter 8.2 Daisy Chain Mode).Pin 11 Chip Select (CSn; active low) selects a device within a network of AS5045 encoders and initiates serial data transfer. A logic high at CSn puts the data output pin (DO) to tri-state and terminates serial data transfer. This pin is also used for alignment mode (Figure 14) and programming mode (Figure 10).Pin 12 PWM allows a single wire output of the 10-bit absolute position value. The value is encoded into a pulse width modulated signal with 1µs pulse width per step (1µs to 4096µs over a full turn). By using an external low pass filter, the digital PWM signal is converted into an analog voltage, making a direct replacement of potentiometers possible.Table 1. Pin DescriptionPin Symbol Type Description1MagINCn DO_OD Magnet Field Mag nitude INC rease; active low, indicates a distance reduction between the magnet and the device surface. See Table 52MagDECn DO_OD Magnet Field Mag nitude DEC rease; active low, indicates a distance increase between the device and the magnet. See Table 53 NC - Must be left unconnected4 NC - Must be left unconnectedPin Symbol Type Description 5 NC - Must be left unconnected6Mode - Select between slow (low, VSS) and fast (high, VDD5V) mode. Internal pull-down resistor.7 VSS S Negative Supply Voltage (GND)8Prog_DI DI_PD OTP Prog ramming Input and Data Input for Daisy Chain mode. Internal pull-down resistor (~74kΩ). Connect to VSS if not used9 DO DO_TD ata O utput of Synchronous Serial Interface10 CLK DI,ST Cl oc k Input of Synchronous Serial Interface; Schmitt-Trigger input11 CSn DI_PU,STC hip S elect, active low; Schmitt-Trigger input, internal pull-up resistor (~50kΩ)12 PWM DO P ulse W idth M odulation of approx. 244Hz; 1µs/step (opt. 122Hz; 2µs/step)13 NC - Must be left unconnected14 NC - Must be left unconnected15VDD3V3 S 3V-Regulator Output, internally regulated from VDD5V. Connect to VDD5V for 3V supply voltage. Do not load externally.16 VDD5V S Positive Supply Voltage, 3.0 to 5.5 VDO_OD digital output open drain S supply pinDO digital output DI digital inputDI_PD digital input pull-down DO_T digital output /tri-stateDI_PU digital input pull-up ST Schmitt-Trigger input6 Electrical Characteristics6.1 AS5045 Differences to AS5040All parameters are according to AS5040 datasheet except for the parameters shown below: Building Block AS5045 AS5040Resolution 12bits, 0.088°/step. 10bit, 0.35°/stepData length Read: 18bits(12bits data + 6 bits status)OTP write: 18 bits(12bits zero position + 6 bits mode selection) Read: 16bits(10bits data + 6 bits status)OTP write: 16 bits(10bits zero position + 6 bits mode selection)Incremental encoder Not usedPin 3: not usedPin 4:not usedQuadrature, step/direction and BLDC motorcommutation modesPin 3:incremental output A_LSB_UPin 4:incremental output B_DIR_VPins 1 and 2 MagINCn, MagDECn: same feature asAS5040, additional OTP option for red-yellow-green magnetic range MagINCn, MagDECn indicate in-range or out-of-range magnetic field plus movement of magnet in z-axisPin 6 MODE pin, switch between fast and slowmodePin 6:Index outputPin 12 PWM output: frequency selectable by OTP:1µs / step, 4096 steps per revolution,f=244Hz 2µs/ step, 4096 steps perrevolution, f=122Hz PWM output:1µs / step, 1024 steps per revolution, 976Hz PWM frequencySampling frequency Selectable by MODE input pin:2.5kHz, 10kHzFixed at 10kHz @10bit resolutionBuilding Block AS5045AS5040 Propagation delay 384µs (slow mode) 96µs (fast mode)48µs Transition noise (rms; 1sigma) 0.03 degrees max. (slow mode) 0.06 degrees max. (fast mode)0.12 degreesOTP programming options Zero position, rotational direction, PWMdisable, 2 Magnetic Field indicator modes, 2 PWM frequenciesZero position, rotational direction, incremental modes, index bit width6.2 Absolute Maximum Ratings (non operating)Stresses beyond those listed under “Absolute Maximum Ratings“ may cause permanent damage to the device. These are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated under “Operating Conditions” is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ParameterSymbol Min Max Unit Note DC supply voltage at pin VDD5V VDD5V -0.3 7 V DC supply voltage at pin VDD3V3 VDD3V35VInput pin voltageV in -0.3VDD5V+0.3 V Except VDD3V3 Input current (latchup immunity) I scr -100 100 mA Norm: JEDEC 78Electrostatic discharge ESD ± 2 kV Norm: MIL 883 E method 3015 Storage temperature T strg-55125°CMin – 67°F ; Max +257°FBody temperature (Lead-free package)T Body 260°C t=20 to 40s,Norm: IPC/JEDEC J-Std-020 Lead finish 100% Sn “matte tin” Humidity non-condensing H585%6.3 Operating ConditionsParameterSymbol Min Typ Max UnitNoteAmbient temperature T amb -40125 °C -40°F…+257°FSupply currentI supp 1621 mA Supply voltage at pin VDD5V Voltage regulator output voltage at pin VDD3V3VDD5V VDD3V3 4.53.0 5.03.3 5.5 3.6 V 5V operationSupply voltage at pin VDD5V Supply voltage at pin VDD3V3 VDD5V VDD3V33.03.03.33.33.6 3.6V3.3V operation(pin VDD5V and VDD3V3 connected)6.4 DC Characteristics for Digital Inputs and Outputs6.4.1 CMOS Schmitt-Trigger Inputs: CLK, CSn. (CSn = internal Pull-up)(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise noted) ParameterSymbol Min Max Unit NoteHigh level input voltage V IH 0.7 * VDD5VV Normal operation Low level input voltage V IL0.3 * VDD5VVSchmitt Trigger hysteresis V Ion- V Ioff 1V-1 1 CLK only Input leakage current Pull-up low level input current I LEAK I iL-30 -100µA µA CSn only, VDD5V: 5.0V6.4.2 CMOS / Program Input: Prog(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)unless otherwise noted) ParameterSymbol Min Max Unit Note High level input voltage VIH 0.7 * VDD5VVDD5VVHigh level input voltage VPROG See Programming ConditionsV During programming Low level input voltage VIL 0.3 * VDD5VVHigh level input current IiL30100µAVDD5V: 5.5V6.4.3 CMOS Output Open Drain: MagINCn, MagDECn(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)unless otherwise noted) ParameterSymbolMinMax UnitNote Low level output voltage V OL VSS+0.4 V Output currentI O4 2mAVDD5V: 4.5V VDD5V: 3VOpen drain leakage current I OZ 1 µA6.4.4 CMOS Output: PWM(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)unless otherwise noted) ParameterSymbolMinMax UnitNoteHigh level output voltage V OH VDD5V-0.5 V Low level output voltage V OL VSS+0.4 V Output current I O4 2mA mAVDD5V: 4.5V VDD5V: 3V6.4.5 Tristate CMOS Output: DO(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise noted) ParameterSymbolMinMax UnitNoteHigh level output voltage V OH VDD5V –0.5VLow level output voltage V OL VSS+0.4 VOutput currentI O4 2mAmAVDD5V: 4.5V VDD5V: 3VTri-state leakage current I OZ 1 µA6.5 Magnetic Input Specification(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)unless otherwise noted)Two-pole cylindrical diametrically magnetised source: ParameterSymbolMinTypMaxUnitNoteDiameter d mag 4 6 mm Thickness t mag 2.5 mm Recommended magnet: Ø 6mm x 2.5mm forcylindrical magnets Magnetic input fieldamplitude B pk 4575 mTRequired vertical component of the magnetic field strength on the die’s surface, measured along a concentric circle with a radius of 1.1mm Magnetic offset B off ± 10mT Constant magnetic stray field Field non-linearity5 %Including offset gradient2.44146 rpm @ 4096 positions/rev.; fast modeInput frequency (rotational speed of magnet)f mag_abs0.61Hz36.6rpm @ 4096 positions/rev.; slow mode Displacement radiusDisp0.25mmMax. offset between defined device center and magnet axis (see Figure 18) Eccentricity Ecc 100µm Eccentricity of magnet center to rotational axis-0.12NdFeB (Neodymium Iron Boron) Recommended magnetmaterial andtemperature drift -0.035%/KSmCo (Samarium Cobalt)6.6 Electrical System Specifications(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0~3.6V (3V operation) VDD5V = 4.5~5.5V (5V operation) unless otherwise noted) ParameterSymbolMinTypMaxUnitNoteResolution RES 12 bit 0.088 deg Integral non-linearity (optimum)INL opt± 0.5 deg Maximum error with respect to the best line fit. Centered magnet without calibration, T amb =25 °C. Integral non-linearity (optimum)INL temp± 0.9 degMaximum error with respect to the best line fit. Centered magnetwithout calibration, T amb = -40 to +125°CIntegral non-linearity INL ± 1.4 degBest line fit =(Err max – Err min ) / 2Over displacement tolerance with 6mm diameter magnet, without calibration,T amb = -40 to +125°C Differential non-linearity DNL ±0.044 deg 12bit, no missing codes 0.06 1 sigma, fast mode (MODE = 1)Transition noiseTN0.03deg RMS1 sigma, slow mode (MODE=0 or open)Power-on reset thresholds On voltage; 300mV typ. hysteresisOff voltage; 300mV typ. hysteresisV on V off 1.37 1.08 2.2 1.9 2.9 2.6VDC supply voltage 3.3V (VDD3V3)DC supply voltage 3.3V (VDD3V3)20Fast mode (Mode = 1); until status bit OCF = 1Power-up timet PwrUp80msSlow mode (Mode = 0 or open); until OCF = 196Fast mode (MODE=1)System propagation delay absolute output : delay of ADC, DSP and absolute interfacet delay384µsSlow mode (MODE=0 or open) 2.48 2.61 2.74T amb = 25°C, slow mode (MODE=0 or open)Internal sampling rate for absolute output:f S2.35 2.61 2.87 kHzT amb = -40 to +125°C, slow mode (MODE=0 or open) 9.90 10.42 10.94T amb = 25°C, fast mode (MODE = 1)Internal sampling rate forabsolute outputf S9.38 10.42 11.46kHz T amb = -40 to +125°C, : fast mode (MODE = 1)Read-out frequency CLK1MHz Max. clock frequency to read out serial dataFigure 3. Integral and Differential Non-linearity (example)Integral Non-Linearity (INL) is the maximum deviation between actual position and indicated position. Differential Non-Linearity (DNL) is the maximum deviation of the step length from one position to the next. Transition Noise (TN) is the repeatability of an indicated position6.7 Timing Characteristics6.7.1Synchronous Serial Interface (SSI)(operating conditions: T amb = -40 to +125°C, VDD5V = 3.0~3.6V (3V operation) VDD5V = 4.5~5.5V (5V operation) unless otherwise noted) ParameterSymbol MinTypMaxUnitNoteData output activated (logic high)t DO active 100 nsTime between falling edge of CSn and dataoutput activated First data shifted to output registert CLK FE500 nsTime between falling edge of CSn and firstfalling edge of CLKStart of data output T CLK / 2 500nsRising edge of CLK shifts out one bit at a timeData output valid t DO valid357 375 394 nsTime between rising edge of CLK and dataoutput validData output tristate t DO tristate100 nsAfter the last bit DO changes back to“tristate”Pulse width of CSn t CSn 500ns CSn = high; To initiate read-out of next angular position Read-out frequencyf CLK>01MHzClock frequency to read out serial data分销商库存信息:AMSAS5045-ASST AS5045-ASSU AS5045 PB AS5045 DB V2AS5045 AB。

April 2010Doc ID 17014 Rev 11/10SEA05Advanced constant voltage and constant current controllerFeatures■Constant voltage and constant current control ■Wide operating V CC range [3.5 - 36] V ■Low quiescent consumption: 200 µA ■Voltage reference: 2.5 V■Voltage control loop accuracy +/- 0.5% ■Current sense threshold: 50 mV ■Open-drain output stage ■Low external component count ■SOT23-6L micro packageApplications■Battery chargers ■AC-DC adapters ■LED driversDescriptionThe SEA05 is a highly integrated solution forSMPS applications requiring a dual control loop to perform CV (constant voltage) and CC (constant current) regulation.The device integrates a voltage reference, two op-amps (with OR-ed open-drain outputs), and a low-side current sensing circuit.The voltage reference, along with one op-amp, is the core of the voltage control loop; the current sensing circuit and the other op-amp make up the current control loop.The external components needed to complete the two control loops are: a resistor divider thatsenses the output of the power supply and fixes the voltage regulation setpoint at the specified value; a sense resistor that feeds the current sensing circuit with a voltage proportional to the dc output current; this resistor determines the current regulation setpoint and must beadequately rated in terms of power dissipation; the frequency compensation components (R-C networks) for both loops.The device, housed in one of the smallest available package, is ideal for space-shrunk applications such as adapters and chargers.Table 1.Device summaryOrder code Package Packing SEA05TRSOT23-6LT ape and reelSOT23 - 6LPin description SEA052/10 Doc ID 17014 Rev 11 Pin descriptionNote:The adjacent pins have the same AMR to increase the robustness of the IC againstaccidental short circuit among pins.Table 2.Pin description Function1IsenseInverting input of the current loop op-amp. The pin is tied to the cold end of the current sense resistor through a decoupling resistor.2GNDGround. Return of the bias current of the device. 0 V reference for all voltages. The pin should be tied as close to the ground output terminal of the converter as possible to minimize load current effect on the voltage regulation setpoint.3Vctrl Inverting input of the voltage loop op-amp. The pin is tied to the mid-point of a resistor divider that senses the output voltage.4IctrlNon-inverting input of the current loop op-amp. It is tied directly to the hot (negative) end of the current sense resistor5OUTCommon open-drain output of the two internal op-amps. The pin, able to sink current only, is connected to the branch of the optocoupler’s photodiode to transmit the error signal to the primary side.6VccSupply Voltage of the device. A small bypass capacitor (0.1 µF typ.) to GND, located as close to IC’s pins as possible, might be useful to get a clean supply voltage.SEA05Maximum ratingsDoc ID 17014 Rev 13/102 Maximum ratings3 Typical application schematicTable 3.Absolute maximum ratingsSymbol Pin ParameterValue Unit Vcc 6Dc supply voltage -0.3 to 38V Vout 5Open-drain voltage -0.3 to VccV Iout 5Max sink current 20mA Ictrl 4Analog input -0.3 to Vcc V Isense 1Analog input -0.3 to 3.3V Vctrl3Analog input-0.3 to 3.3VTable 4.Thermal dataSymbol ParameterValue Unit R thJA Thermal resistance, junction-to-ambient 250°C/W Tj op Junction temperature operating range -40 to 150°CT STGStorage temperature-55 to 150Electrical characteristics SEA054/10 Doc ID 17014 Rev 14 Electrical characteristics-25 °C <T J < 125 °C, V CC = 20 V; unless otherwise specified Table 5.Electrical characteristicsSymbol ParameterTest conditionMin.Typ.Max.UnitDevice supply Vcc Voltage operating range 3.536V IccQuiescent current (Ictrl =Isense = 0 V , OUT = open)200300µAVoltage control loop op-amp Gm v Transconductance (sink current only) (1)1.If the voltage on Vctrl (the negative input of the amplifier) is higher than the positive amplifier input, and it isincreased by 1 mV, the sinking current at the output OUT is increased by 3.5 mA.1 3.5S V ctrl Voltage reference default value (2)2.The internal voltage reference is set at 2.5 V. The voltage control loop precision takes into account thecumulative effects of the internal voltage reference deviation as well as the input offset voltage of thetransconductance operational amplifier. The internal Voltage Reference is fixed by bandgap, and trimmed to 0.48 % accuracy at room temperature.T J = 25 °C2.488 2.52.512V 2.482.52IbiasInverting input bias current25nACurrent control loop Gm iTransconductance (sink current only) (3)3.When the positive input at Ictrl is lower than -50 mV, and the voltage is decreased by 1 mV, the sinkingcurrent at the output out is increased by 7 mA. 1.57SVcsth Current sense threshold V csth = V (Isense)-V (Ictrl) (4)@ I (Iout) = 1 mA4.Considering Ictrl pin directly connected to the hot (negative) end of the current sense resistor and Isensepin connected to the cold end of the current sense resistor through a decoupling resistor (see fig.3), the internal current sense threshold is triggered when the voltage on pin Ictrl is -50 mV. The current loopreference precision takes into account the cumulative effects of the internal voltage reference deviation as well as the input offset voltage of the transconductance operational amplifier.465054mVIbias Non-inverting input source current @ V(Ictrl) = -50 mV6µAOutput stage V OUTlowLow output level @ 2 mA sink current200400mVSEA05Application informationDoc ID 17014 Rev 15/105 Application informationNote:A 15 Ω resistor in series to Ictrl pin helps to protect the IC in case of negative voltage that exceed the AMR of Ictrl pin.As example a potential dangerous phenomenon could happen during converter output short-circuit.Consider the steady state operation of the circuit during voltage mode regulation (i.e. the output is at its nominal voltage). The output capacitor is fully charged at V o . If an abrupt short (i.e. with negligible impedance) is applied at the output, instantly the positive pin of the electrolytic capacitor is connected to the SEA05 ground. Since the capacitor acts like a battery, all its voltage is applied across the R sense pin and therefore the Ictrl pin is pulled down to –Vo. This could damage the IC in case the Ictrl pin AMR is violated.In reality the short is not so severe because it has a some impedance, the electrolyticcapacitor has an ESR and it starts discharging as soon as the short is applied. The Ictrl pin is brought to a negative voltage anyway. The pin internal structure has been design to be robust against negative voltage but, since the severity of this phenomenon is proportional to the output voltage, for some applications an external resistor in series with Ictrl pin helps protect the IC.The resistor added in series with Ictrl pin introduces an error in the current sense threshold voltage.This error can be calculated considering the Ictrl pin current: this current multiplied by the value of the external resistor gives the current sense threshold variation.As example if we add a 15 Ω resistor in series to Ictrl pin, we have I ctrl current = Ibias = 6 µA and therefore the error 6 µA x 15 Ω = 80 µV , the error is 80 µV / 50 mV = 0.16%Voltage and current control SEA056/10 Doc ID 17014 Rev 16 Voltage and current control6.1 Voltage controlThe voltage loop is controlled via a first transconductance operational amplifier, the voltagedivider R1, R2, and the optocoupler which is directly connected to the output. Its possible to choose the values of R1 and R2 resistors using Equation 1-2:Equation 1Equation 2where Vo is the desired output voltage.As an example, with R1 = 100 k Ω and R2 = 15 k Ω Vo = 19.17 V6.2 Current controlThe current loop is controlled via the second trans-conductance operational amplifier, thesense resistor R sense , and the optocoupler. The control equation verifies:Equation 3Equation 4where I omax is the desired limited current, and V csth is the threshold voltage for the current control loop.As an example, with I omax = 1 A, V csth = 50 mV , then R sense = 50 m Ω.Note that the R sense resistor should be chosen taking into account the maximum dissipation (Plim) through it during full load operation.Equation 5As an example, with I omax = 1 A, and V csth= 50 mV, Plim = 50 mW.Therefore, for most adaptor and battery charger applications, it is suitable a low power resistor to make the current sensing function.VcsthI R max o sense=∗P Lim V csth l omax⋅=SEA05Compensation V csth threshold is achieved internally by a voltage divider tied to an internal voltagereference. Its middle point is tied to the positive input of the current control operationalamplifier, and its foot has to be connected to lower potential point of the sense resistor asshown in Figure4. The resistors of this voltage divider are matched to provide the bestpossible precision. The current sinking outputs of the two trans-conductance operationalamplifiers are common (to the output of the IC). This makes an ORing function whichensures that whenever the current or the voltage reaches too high values, the optocoupler isactivated.The relation between the controlled current and the controlled output voltage can bedescribed with a square characteristic as shown in the following V/I output-power graph.(with power supply of the device independent from the output voltage)7 CompensationThe voltage control trans-conductance operational amplifier can be fully compensated. Bothof its output and negative input are directly accessible for external compensationcomponents as shown in Figure4.Doc ID 17014 Rev 17/10Package mechanical data SEA058/10 Doc ID 17014 Rev 18 Package mechanical dataIn order to meet environmental requirements, ST offers these devices in different grades of ECOPACK ® packages, depending on their level of environmental compliance. ECOPACK ® specifications, grade definitions and product status are available at: . ECOPACK ® is an ST trademark.Note:Dimensions per JEDEC MO178ABFigure 6.SOT23-6L package dimensionsTable 6.SOT23-6L mechanical dataDim.mm. inchMin.Typ.Max.Min.Typ.Max.A 0.9 1.45 0.035 0.057A1 0 0.1 0 0.0039A2 0.9 1.3 0.035 0.0512 b0.35 0.50.014 0.02c 0.09 0.2 0.004 0.008 D2.83.050.11 0.120E 1.5 1.75 0.059 0.0689 e 0.95 0.037H2.6 30.102 0.118L 0.1 0.6 0.004 0.024 θ (degrees)0° 10°0° 10°SEA05Revision historyDoc ID 17014 Rev 19/109 Revision historyTable 7.Document revision historyDate RevisionChanges26-Apr-20101Initial release.SEA05Please Read Carefully:Information in this document is provided solely in connection with ST products. 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