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参数资料
| 型号: | MAX613CSD |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 6/8页 |
| 文件大小: | 0K |
| 描述: | IC PWR CNTRLR ANLG PCMCIA 14SOIC |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 50 |
| 类型: | PCMCIA/Cardbus 开关 |
| 输出数: | 2 |
| 内部开关: | 是 |
| 输入电压: | 2.85 V ~ 5.5 V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 14-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 14-SOIC |
| 包装: | 管件 |
��
�
�Dual-Slot� PCMCIA�
�Analog� Power� Controllers�
�VCC� Switching�
�The� MAX613/MAX614� contain� level� shifters� that� simplify�
�driving� external� power� MOSFETs� to� switch� PCMCIA� card�
�Table� 3.� MAX613� DRV3� and� DRV5� Control�
�–� —� —� —�
�Logic� (� S� H� D� N� =� VCCIN)�
�VCC.� While� a� PCMCIA� card� is� being� inserted� into� the�
�socket,� the� VCC� pins� on� the� card� edge� connector� should�
�LOGIC� INPUT�
�OUTPUT�
�be� powered� down� to� 0V� to� prevent� “hot� insertion”� that�
�may� damage� the� PCMCIA� card.� The� MAX613/MAX614�
�MOSFET� drivers� are� open� drain.� Their� rise� time� is� con-�
�trolled� by� an� external� pull-up� resistor,� allowing� slow� turn-�
�on� of� VCC� power� to� the� PCMCIA� card.�
�The� DRV3� and� DRV5� pins� on� the� MAX613� and� the� DRV�
�pin� on� the� MAX614� are� open-drain� outputs� pulled� down�
�VCC1�
�0�
�0�
�1�
�1�
�VCC0�
�0�
�1�
�0�
�1�
�DRV3�
�0V�
�HI-Z�
�0V�
�0V�
�DRV5�
�0V�
�0V�
�HI-Z�
�0V�
�with� internal� N-channel� devices.� The� gate� drive� to�
�these� internal� N-channel� devices� is� powered� from�
�VCCIN,� regardless� of� VPPIN’s� voltage.� If� VCCIN� is� left�
�unconnected� or� less� than� 2V� is� applied� to� VCCIN,� the�
�DRV3/DRV5/DRV� gate� drivers� will� not� sink� current.�
�To� switch� VCC� (M1� and� M2� in� Figure� 1),� use� external�
�N-channel� power� MOSFETs.� M1� and� M2� should� be�
�logic-level� N-channel� power� MOSFETs� with� low� on�
�resistance.� The� Motorola� MTP3055EL� and� Siliconix�
�Si9956DY� MOSFETs� are� both� good� choices.� Turn� on�
�M1� and� M2� by� pulling� their� gates� above� +5V.� With� the�
�gates� pulled� up� to� VPPIN� as� shown� in� Figure� 1,� VPPIN�
�should� be� at� least� 10V� so� that� with� VCC� =� 5.5V,� M1� and�
�M2� have� at� least� 4.5V� of� gate� drive.�
�Table� 1.� AVPP� Control� Logic�
�The� gates� of� M1� and� M2� can� be� pulled� up� to� any� 10V� to�
�20V� source,� and� do� not� need� to� be� pulled� up� to� VPPIN.�
�Typically,� the� +12V� used� for� VPPIN� is� supplied� from� a�
�+5V� to� +12V� switching� regulator.� To� save� power,� the�
�+5V� to� +12V� switching� regulator� can� be� shut� down�
�when� not� using� the� VPP� programming� voltage,� allowing�
�VPPIN� to� fall� below� +5V.�
�In� this� case,� M1� and� M2� should� not� be� pulled� up� to�
�VPPIN,� since� M1� and� M2� cannot� be� turned� on� reliably�
�when� VPPIN� falls� below� +10V.� Any� clock� source� can�
�be� used� to� generate� a� high-side� gate-drive� voltage� by�
�using� capacitors� and� diodes� to� build� an� inexpensive�
�charge� pump.� Figure� 3� shows� a� charge-pump� circuit�
�that� generates� 10V� from� a� +5V� logic� clock� source.�
�__________Applications� Information�
�The� MAX613� contains� all� the� gate� drivers� and� switch-�
�LOGIC� INPUT�
�OUTPUT�
�ing� circuitry� needed� to� support� a� +3.3V/+5V� VCC�
�PCMCIA� slot� with� minimal� external� components.�
�AVPP1�
�0�
�0�
�1�
�1�
�AVPP0�
�0�
�1�
�0�
�1�
�AVPP�
�0V�
�VCCIN�
�VPPIN�
�HI-Z�
�Figure� 4� shows� the� analog� power� control� necessary� to�
�support� two� dual� voltage� PCMCIA� slots.� The� A:VCC�
�and� B:VCC� pins� on� the� Intel� 82365SL� DF� power� the�
�drivers� for� the� control� signals� that� directly� connect� to�
�the� PCMCIA� card.�
�A� 3.3V� card� needs� 3.3V� logic-level� control� signals� and�
�the� capability� to� program� VPP1� and� VPP2� to� 3.3V.� The�
�MAX613’s� VCCIN� is� switched� with� slot� VCC,� so� AVPP0�
�Table� 2.� BVPP� Control� Logic�
�=� 1� and� AVPP1� =� 0� causes� AVPP� =� slot� VCC.�
�Likewise,� A:VCC� and� B:VCC� are� connected� to� VCCIN,�
�LOGIC� INPUT�
�OUTPUT�
�so� the� Intel� 82365SL� DF� control� signals� to� the� PCMCIA�
�card� are� the� right� logic� levels.�
�BVPP1�
�0�
�0�
�1�
�1�
�BVPP0�
�0�
�1�
�0�
�1�
�BVPP�
�0V�
�VCCIN�
�VPPIN�
�HI-Z�
�PCMCIA� card� interface� controllers� other� than� the�
�Intel� 82365SL� DF� can� be� used� with� Figure� 4� ’s� cir-�
�cuit.� Table� 4� shows� the� pins� on� the� Cirrus� Logic�
�CL-PD6720� that� perform� the� same� function� as� the�
�Intel� 82365SL� DF� pins.�
�6�
�_______________________________________________________________________________________�
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相关代理商/技术参数 |
参数描述 |
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| MAX613CSD+T | 功能描述:接口 - 专用 RoHS:否 制造商:Texas Instruments 产品类型:1080p60 Image Sensor Receiver 工作电源电压:1.8 V 电源电流:89 mA 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:BGA-59 |
| MAX613CSD-T | 功能描述:接口 - 专用 RoHS:否 制造商:Texas Instruments 产品类型:1080p60 Image Sensor Receiver 工作电源电压:1.8 V 电源电流:89 mA 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:BGA-59 |
| MAX613EPD | 功能描述:接口 - 专用 RoHS:否 制造商:Texas Instruments 产品类型:1080p60 Image Sensor Receiver 工作电源电压:1.8 V 电源电流:89 mA 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:BGA-59 |
| MAX613ESD | 功能描述:接口 - 专用 RoHS:否 制造商:Texas Instruments 产品类型:1080p60 Image Sensor Receiver 工作电源电压:1.8 V 电源电流:89 mA 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:BGA-59 |
| MAX613ESD+ | 功能描述:接口 - 专用 RoHS:否 制造商:Texas Instruments 产品类型:1080p60 Image Sensor Receiver 工作电源电压:1.8 V 电源电流:89 mA 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:BGA-59 |
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