- 您现在的位置:买卖IC网 > PDF目录16587 > MCZ33099CEG (Freescale Semiconductor)IC VREG ALTERNATOR ADAPT 16-SOIC PDF资料下载
参数资料
| 型号: | MCZ33099CEG |
| 厂商: | Freescale Semiconductor |
| 文件页数: | 10/18页 |
| 文件大小: | 0K |
| 描述: | IC VREG ALTERNATOR ADAPT 16-SOIC |
| 标准包装: | 47 |
| 应用: | 自动 |
| 电流 - 电源: | 6.5mA |
| 电源电压: | 7 V ~ 18 V |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SOIC(0.295",7.50mm 宽) |
| 供应商设备封装: | 16-SOIC W |
| 包装: | 管件 |
��
�
�TYPICAL� APPLICATIONS�
�Modulated� (PWM)� waveform� having� a� variable� ON� /� OFF� duty�
�cycle� ratio� that� is� determined� by� an� analog� or� a� digital� duty�
�cycle� control� circuitry� that� responds� to� variations� in� the�
�system� voltage� due� to� variations� in� system� load� current.� The�
�PWM� waveform� has� a� duty� cycle� regulation� output� frequency�
�of� about� 395� Hz� (f� dc� )� defined� by� an� 8-bit� division� of� an� internal�
�101� kHz� oscillator� clock� frequency� (f� osc� ).� The� GATE� voltage�
�at� the� GATE� pin� is� due� to� a� charge� pump� GATE� voltage� (V� g� )�
�generated� by� voltage� multiplication� using� an� internal� charge�
�pump� voltage� regulator.� The� high� GATE-to-source� voltage�
�applied� to� the� external� MOSFET� during� the� ON� cycle� of� the�
�PWM� waveform� minimizes� a� low� drain-to-source� ON�
�resistance� (R� DS(ON)� )� and� associated� drain-to-source� voltage�
�V� d(SAT)� to� maximize� the� field� current� while� minimizing� the�
�associated� power� dissipation� in� the� MOSFET.�
�A� unique� feature� of� the� 33099� is� the� combinational� use� of�
�analog� and� digital� duty� cycle� controllers� to� provide� a� Load�
�Response� Control� (LRC)� duty� cycle� function� when� rotor�
�frequency� f� ph� is� less� than� frequency� f� 2� .� A� classic� analog� duty�
�cycle� function� is� provided� at� the� GATE� output� when�
�frequency� f� ph� is� greater� than� frequency� f� 2� .� During� the� LRC�
�mode� when� f� 1� <� f� ph� <� f� 2� ,� a� sudden� decrease� in� the� system�
�voltage� due� to� a� sudden� increase� in� system� load� current� will�
�cause� the� analog� duty� cycle� to� rapidly� increase� to� as� great� as�
�100%.� However,� the� LRC� circuitry� causes� the� digital� duty�
�cycle� to� increase� to� 100%� at� a� controlled� predetermined� LRC�
�rate� and� overrides� the� analog� duty� cycle.� Thus� the� alternator�
�response� time� is� decreased� in� the� LRC� mode� and� prevents�
�the� alternator� from� placing� a� sudden� high� torque� load� on� the�
�automobile� engine� during� this� slow� RPM� mode.� This� can�
�occur� when� a� high� current� accessory� is� switched� on� to� the� 12�
�V� system,� producing� a� sudden� drop� in� system� voltage.� When�
�frequency� f� ph� is� greater� than� frequency� f� 2� ,� the� slow� LRC�
�response� is� not� in� effect� and� the� analog� duty� cycle� controller�
�controls� the� PWM� voltage� waveform� applied� to� the� external�
�MOSFET� to� regulate� the� system� voltage.� By� selectively�
�coupling� the� LRC1� and� LRC2� pins� to� ground� or� leaving� them�
�open,� the� user� can� program� four� different� LRC� rates� (R� lrc1� -�
�R� lrc4� )� from� 9.37%/sec� to� 37.4%/sec.� During� an� initial� ignition�
�ON� and� engine� start-up,� the� LRC� rate� is� also� in� effect� to�
�minimize� alternator� torque� loading� on� the� engine� during� start,�
�even� when� a� Wide� Open� Throttle� (WOT)� condition� (f� ph� >� f� 2� )�
�occurs.�
�An� internal� N-Channel� MOSFET� is� provided� on� the� IC� to�
�directly� drive� lamp� current� as� a� fault� indicator.� The� fault� lamp�
�is� connected� between� the� low� side� of� the� ignition� switch� and�
�the� LAMP� DRAIN� pin� of� the� IC.� A� fault� is� indicated� during� an�
�undervoltage� battery� condition� when� frequency� f� ph� is� greater�
�than� frequency� f� 2� ,� during� an� overvoltage� battery� condition,�
�and� when� frequency� f� ph� is� less� than� frequency� f� 1� .� Frequency�
�f� ph� <� f� 1� when� an� insufficient� alternator� output� voltage� results�
�or� a� slow� or� non-rotating� rotor� occurs� due� to� a� slipping� or�
�broken� belt.� An� external� LAMP� GATE� pin� is� also� provided� for�
�the� internal� lamp� driver� to� allow� the� user� to� override� the�
�internal� IC� fault� logic� and� externally� drive� the� internal� lamp�
�drive� MOSFET.�
�When� a� loose� wire� or� battery� pin� corrosion� causes� the�
�Remote� voltage� to� decrease� but� is� not� a� Remote� Open�
�condition,� the� system� voltage� will� increase,� causing� an�
�overvoltage� Lamp� fault� indication,� and� is� regulated� at� a�
�secondary� value� of� about� 18.5� V.�
�During� a� system� load� dump� condition,� load� dump�
�protection� circuitry� prevents� GATE-to-source� drive� to� the�
�external� MOSFET� and� to� the� internal� lamp� drive� MOSFET.�
�This� ensures� that� neither� the� field� current� nor� the� lamp�
�current� is� activated� during� load� dump� conditions.� A� drain-to-�
�GATE� voltage� clamp� is� also� provided� for� the� internal� lamp�
�driver� for� further� protection� of� this� driver� during� load� dump.�
�An� ignition� pin� (IGN)� is� provided� to� activate� the� regulator�
�from� the� standby� mode� into� a� normal� operating� mode� when�
�the� ignition� switch� is� ON� and� an� ignition� voltage� (V� ign� )� is�
�greater� than� a� power� up/down� ignition� threshold� voltage�
�(V� Tign� ).� When� the� ignition� switch� is� OFF,� voltage� V� ign� is� less�
�than� voltage� V� Tign� ,� and� the� regulator� is� switched� into� a� low�
�current� standby� mode,� when� frequency� f� ph� <� f� 1� .� The� IGN� pin�
�can� either� be� coupled� to� the� low� side� of� the� ignition� switch� or�
�to� the� low� side� of� the� lamp.� When� the� IGN� pin� is� connected� to�
�the� low� side� of� the� lamp,� the� lamp� must� be� shunted� by� a�
�resistor� to� ensure� that� ignition� ON� is� sensed,� even� with� an�
�OPEN� lamp� fault� condition.� When� the� lamp� in� ON,� lamp�
�current� is� polled� OFF� periodically� at� an� ignition� polling�
�frequency� in� order� for� the� IGN� pin� to� periodically� sense� that�
�the� ignition� voltage� is� high� even� though� the� lamp� is� ON.� An�
�ignition� input� pull-down� current� (I� ign� )� is� provided� to� pull�
�voltage� V� ign� to� ground� when� the� IGN� pin� is� OPEN� or�
�terminated� on� a� high� resistance.�
�Two� ground� pins� are� provided� by� the� 33099� to� separate�
�sensitive� analog� circuit� ground� (AGND)� from� noisy� digital� and�
�high-current� ground� (GND).�
�ALTERNATOR� REGULATOR� BIASING� AND�
�POWER� UP/DOWN�
�The� biasing� of� the� regulator� is� derived� from� the� BAT� pin�
�voltage� V� bat� .� In� the� normal� operating� mode� when� the� ignition�
�switch� is� ON� and� voltage� V� ign� is� greater� than� V� Tign� (about�
�1.25� V),� a� 5.0� V� V� DD� voltage� regulator� biases� the� IC� logic� and�
�provides� bias� to� a� bandgap� shunt� voltage� regulator.� The�
�bandgap� regulator� maintains� a� reference� voltage� (V� ref� )� of�
�approximately� 2.0� V� with� an� internal� negative� temperature�
�coefficient� (-TC)� as� well� as� a� 1.25� V� Zero� Temperature�
�Coefficient� (OTC)� reference� voltage.� Additional� bias� currents�
�and� reference� voltages,� including� a� charge� pump� GATE�
�voltage� V� g� ,� are� also� generated� from� voltage� V� bat� .� The�
�typically� ignition� ON� drain� current� (I� Q1(on)� )� is� about� 6.5� mA� at�
�25°C.� When� the� ignition� switch� is� OFF� and� voltage� V� ign� is�
�less� than� V� Tign� ,� the� regulator� is� in� a� low� current� standby�
�mode,� having� a� standby� drain� current� of� about� 0.7� mA�
�(I� Q1(off)� )� at� 25°C.� During� the� sleep� mode,� some� internal�
�voltage� regulators� and� bias� currents� are� either� terminated� or�
�minimized.� However,� the� V� DD� regulator� and� the� bandgap�
�voltage� regulator� continue� to� maintain� voltages� V� DD� for� the�
�logic,� the� 2.0� V� V� ref� ,� and� the� 1.25� V� reference� voltage.� In�
�addition,� all� logic� is� reset� in� the� standby� mode.�
�After� switching� the� ignition� switch� to� the� ON� position,�
�voltage� V� ign� will� exceed� voltage� V� Tign� ,� causing� comparator�
�C� ign� to� switch� states,� providing� an� ignition-ON� signal� to� the�
�Ignition� Delay� circuit.� After� an� Ignition� start� Delay� Time� of�
�500� ms,� the� Ignition� Delay� circuit� activates� additional� current�
�33099�
�Analog� Integrated� Circuit� Device� Data�
�10�
�Freescale� Semiconductor�
�相关PDF资料 |
PDF描述 |
|---|---|
| V300B24E150BG | CONVERTER MOD DC/DC 24V 150W |
| GMM10DRMH | CONN EDGECARD 20POS .156 WW |
| EVAL-ADCMP600BRJZ | BOARD EVAL FOR ADCMP600 SOT23-5 |
| EVAL-AD5263EBZ | BOARD EVAL AD5263 |
| MC34702EKR2 | IC POWER SUPPLY MCU 3A 32-SOIC |
相关代理商/技术参数 |
参数描述 |
|---|---|
| MCZ33099CEGR2 | 功能描述:线性稳压器 - 标准 ALT. VOLT REG 14.6 RoHS:否 制造商:STMicroelectronics 输出类型: 极性: 输出电压:1.8 V 输出电流:150 mA 负载调节: 最大输入电压:5.5 V 线路调整率: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOT-323-5L |
| MCZ33099EG | 功能描述:线性稳压器 - 标准 ALT. VOLT REG 14.8 RoHS:否 制造商:STMicroelectronics 输出类型: 极性: 输出电压:1.8 V 输出电流:150 mA 负载调节: 最大输入电压:5.5 V 线路调整率: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOT-323-5L |
| MCZ33099EGR2 | 功能描述:线性稳压器 - 标准 ALT. VOLT REG 14.8 RoHS:否 制造商:STMicroelectronics 输出类型: 极性: 输出电压:1.8 V 输出电流:150 mA 负载调节: 最大输入电压:5.5 V 线路调整率: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOT-323-5L |
| MCZ33198EF | 功能描述:功率驱动器IC CHARGE PUMP IC RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| MCZ33198EFR2 | 功能描述:功率驱动器IC CHARGE PUMP IC RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
发布紧急采购,3分钟左右您将得到回复。