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| 型号: | MAX11008BETM+ |
| 厂商: | Maxim Integrated |
| 文件页数: | 29/67页 |
| 文件大小: | 0K |
| 描述: | IC CTLR LDMOS BIAS DUAL 48TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 43 |
| 功能: | 偏压控制器 |
| RF 型: | 手机 |
| 次要属性: | 片上 4Kb EEPROM |
| 封装/外壳: | 48-WFQFN 裸露焊盘 |
| 包装: | 托盘 |
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��
�
�Dual� RF� LDMOS� Bias� Controller� with�
�Nonvolatile� Memory�
�ADC� and� DAC� References�
�The� MAX11008� provides� an� internal� low-noise� +2.5V�
�reference� for� the� ADCs,� DACs� and� temperature� sensor.�
�When� using� the� internal� reference� the� REFDAC� and�
�REFADC� inputs� can� either� be� left� open� or� to� improve�
�noise� performance,� bypassed� with� a� 0.1μF� capacitor� to�
�AGND.� Connect� a� voltage� source� to� the� REFADC� input�
�ranging� between� +1V� to� AV� DD� to� configure� the� device�
�for� external� ADC� reference� mode.� Connect� a� voltage�
�source� to� the� REFDAC� input� ranging� between� +0.7V� to�
�+2.5V� to� configure� the� device� for� external� DAC� refer-�
�ence� mode.� When� using� an� external� voltage� reference,�
�bypass� the� REFDAC� and� REFADC� inputs� with� a� 0.1μF�
�capacitor� to� AGND.� Bits� D[3:0]� within� the� Hardware�
�Configuration� register� control� the� source� of� the� DAC�
�and� ADC� references.� See� Table� 11.�
�Temperature� Sensors�
�The� MAX11008� measures� the� internal� die� temperature�
�and� two� external� LDMOS� transistor� temperatures� through�
�one� internal� and� two� external� diode-connected� transis-�
�tors.� The� MAX11008� performs� temperature� measure-�
�ments� by� changing� the� bias� current� of� each� diode� from�
�4μA� to� 68μA� to� produce� a� temperature-dependent� bias�
�voltage� difference.� The� internal� ADC� converts� the� volt-�
�age� difference� to� a� digital� value.� The� conversion� result� at�
�4μA� is� subtracted� from� the� conversion� results� at� 68μA� to�
�calculate� a� digital� value� that� is� proportional� to� absolute�
�temperature.� The� output� data� sent� to� the� master� will� be�
�the� resultant� digital� code� minus� an� offset� value� to� adjust�
�from� Kelvin� to� Celsius.� Temperature� data� is� delivered� to�
�the� master� as� a� 12-bit� signed� (two’s� complement)� frac-�
�tional� number� with� the� 3� LSBs� being� the� fractional� bits.�
�This� provides� a� temperature� measurement� resolution� of�
�1/8°C.� See� Table� 3� for� examples� of� the� signed� fractional�
�number� digital� temperature� codes.�
�Table� 3.� Signed� Fractional� Number�
�Temperature-Code� Examples�
�In� clock� mode� 00,� initiate� temperature� conversions� by�
�writing� 0x13� to� the� ADC� Conversion� register.� In� clock�
�mode� 01,� initiate� temperature� conversions� by� writing�
�0x13� to� the� ADC� Conversion� register� and� pulse� CNVST�
�low.� In� clock� mode� 11,� initiate� temperature� conversions�
�by� writing� 0x13� to� the� ADC� Conversion� register� and�
�pulse� CNVST� low� for� each� channel� conversion.� Set� the�
�corresponding� data� bits� for� the� temperature� sensor� to�
�be� measured� to� 1� (see� the� ADC� Conversion� Register�
�(ADCCON)� (Write� Only)� section� and� Table� 20)� for� all�
�three� clock� modes.� Set� the� high� and� low� external� tem-�
�perature� thresholds� through� the� temperature� threshold�
�registers.� See� the� Low� Temperature� Threshold�
�Registers� (TL1,� TL2)� (Read/Write)� section,� High�
�Temperature� Threshold� Registers� (TH1,� TH2)�
�(Read/Write)� section,� and� Tables� 7� and� 8).�
�The� reference� voltage� for� the� temperature� measure-�
�ments� is� always� derived� from� the� internal� reference�
�source� to� ensure� that� 1� LSB� corresponds� to� 1/8� of� a�
�degree� Celsius.� On� every� scan� where� only� temperature�
�measurements� are� requested,� temperature� conversions�
�are� carried� out� in� the� following� order:� INTEMP,�
�EXTEMP1,� then� EXTEMP2.� If� the� ADCMON� bit� is� set�
�when� the� conversions� are� performed,� the� temperature�
�readings� are� available� in� the� FIFO.�
�The� temperature-sensing� circuits� power� up� at� the� start�
�of� an� ADC� conversion� scan.� The� temperature-sensing�
�circuits� remain� powered� on� until� the� end� of� the� scan� to�
�avoid� a� 50μs� delay� caused� by� the� internal� reference�
�power-up� time� required� for� each� individual� temperature�
�channel.� The� temperature-sensor� circuits� remain� pow-�
�ered� up� when� the� ADC� conversion� register’s� continu-�
�ous� convert� bit� (CONCONV,� see� Table� 20)� is� set� to� 1�
�and� the� current� ADC� conversion� includes� a� tempera-�
�ture� channel.� The� temperature-sensor� circuits� remain�
�powered� up� until� the� CONCONV� bit� is� set� low.�
�The� external� temperature-sensor� drive� current� ratio� has�
�been� optimized� for� a� 2N3904� npn� transistor� with� an� ide-�
�ality� factor� of� 1.0065.� The� nonideality� offset� is� removed�
�TEMPERATURE�
�(°C)�
�-40�
�-1.625�
�0�
�+27.125�
�+105�
�DIGITAL� CODE�
�[D11:0]�
�1110� 1100� 0000�
�1111� 1111� 0011�
�0000� 0000� 0000�
�0000� 1101� 1001�
�0011� 0100� 1000�
�internally� by� a� preset� digital� coefficient.� Using� a� transis-�
�tor� with� a� different� ideality� factor� produces� a� proportion-�
�ate� difference� in� the� absolute� measured� temperature.�
�For� more� details� on� this� topic� and� others� related� to�
�using� an� external� temperature� sensor,� refer� to�
�Application� Note� 1057:� Compensating� for� Ideality�
�Factor� and� Series� Resistance� Differences� between�
�Thermal� Sense� Diodes� and� Application� Note� 1944:�
�Temperature� Monitoring� Using� the� MAX1253/54� and�
�MAX1153/54.�
�______________________________________________________________________________________�
�29�
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| MAX11008BETM+ | 功能描述:射频放大器 Dual RF LDMOS Bias Controller w/NV Mem RoHS:否 制造商:Skyworks Solutions, Inc. 类型:Low Noise Amplifier 工作频率:2.3 GHz to 2.8 GHz P1dB:18.5 dBm 输出截获点:37.5 dBm 功率增益类型:32 dB 噪声系数:0.85 dB 工作电源电压:5 V 电源电流:125 mA 测试频率:2.6 GHz 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:QFN-16 封装:Reel |
| MAX11008BETM+T | 功能描述:射频放大器 Dual RF LDMOS Bias Controller w/NV Mem RoHS:否 制造商:Skyworks Solutions, Inc. 类型:Low Noise Amplifier 工作频率:2.3 GHz to 2.8 GHz P1dB:18.5 dBm 输出截获点:37.5 dBm 功率增益类型:32 dB 噪声系数:0.85 dB 工作电源电压:5 V 电源电流:125 mA 测试频率:2.6 GHz 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:QFN-16 封装:Reel |
| MAX11008EVC16 | 功能描述:放大器 IC 开发工具 MAX11008 Eval Kit RoHS:否 制造商:International Rectifier 产品:Demonstration Boards 类型:Power Amplifiers 工具用于评估:IR4302 工作电源电压:13 V to 23 V |
| MAX11008EVKIT+ | 功能描述:放大器 IC 开发工具 MAX11008 Eval Kit RoHS:否 制造商:International Rectifier 产品:Demonstration Boards 类型:Power Amplifiers 工具用于评估:IR4302 工作电源电压:13 V to 23 V |
| MAX1100CWG | 制造商:Rochester Electronics LLC 功能描述: 制造商:Maxim Integrated Products 功能描述: |
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