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参数资料
| 型号: | MAX19713EVCMODU+ |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 8/21页 |
| 文件大小: | 0K |
| 描述: | EVAL MODULE FOR MAX19713 |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 1 |
| 主要目的: | 接口,模拟前端(AFE) |
| 嵌入式: | 否 |
| 已用 IC / 零件: | MAX19713 |
| 主要属性: | 双路 45MSPS 10 位 Rx ADC 和 Tx DAC |
| 次要属性: | 图形用户接口,SPI? 和 USB 接口 |
| 已供物品: | 2 板,CD |
��
�
�MAX19710–MAX19713� Evaluation�
�Kits/Evaluation� Systems�
�Separate� analog,� digital,� clock,� and� buffer� power� planes�
�minimize� noise� coupling� between� analog� and� digital� sig-�
�nals.� Analog� ADC� inputs� and� DAC� outputs� use� 100� Ω�
�differential� microstrip� transmission� lines,� while� 50� Ω�
�microstrip� transmission� lines� are� used� for� all� digital� out-�
�puts� and� the� clock� input.� The� trace� lengths� of� the� ADC�
�input� and� DAC� output� paths� are� well� matched� to� mini-�
�mize� layout-dependent� input-signal� skew.�
�Power� Supplies�
�For� optimal� performance,� the� MAX19710–MAX19713�
�EV� kits� require� separate� analog,� digital,� clock,� and�
�buffer� power� supplies;� however,� two� separate� +3.0V�
�and� +1.8V� power� supplies� are� recommended� to� power�
�the� analog� (VDD)� and� digital� (OVDD)� portions� of� the�
�AFEs,� respectively.� The� clock� circuitry� (CVDD)� is� pow-�
�ered� by� a� +3.0V� power� supply.� The� DAC� outputs� are�
�buffered� by� split-supply� op� amps.� Power� the� positive�
�rail� (VOP)� with� a� +5V� supply� and� the� negative� rail�
�(VON)� with� a� -5V� supply.� A� separate� +1.8V� power� sup-�
�ply� (BVCC)� can� be� used� to� isolate� the� power� source� to�
�the� buffer� driver� (U2).� See� Table� 1� for� the� proper�
�jumper� configurations� for� JU3.�
�Table� 1.� U2� Power� Source� (JU3)�
�SHUNT�
�DESCRIPTION�
�POSITION�
�clock� voltage� supply� (CVDD)� is� set� to� +3.0V.� The� clock�
�signal� is� available� at� J2-3� (CLKOUT),� which� can� be� used�
�to� synchronize� the� output� signal� to� the� logic� analyzer.�
�Measure� the� clock� signal� with� an� oscilloscope� at� TP3.�
�Rx� ADC� Inputs�
�Although� the� MAX19710–MAX19713� AFEs� accept� differ-�
�ential� analog� input� signals,� the� EV� kits� only� require� a�
�single-ended� analog� input� signal� provided� by� the� user.�
�Connect� the� single-ended� sources� to� the� IA� SMA� con-�
�nector� (I� channel)� and� QA� SMA� connector� (Q� channel).�
�Insertion� losses� due� to� series-connected� bandpass�
�filters� and� the� interconnecting� cables� decrease� the�
�amount� of� power� seen� at� the� EV� kit� input.� Account� for�
�these� losses� when� setting� the� signal� generator�
�amplitude.� On-board� transformers� (T1,� T2)� convert� the�
�single-ended� analog� input� signals� and� generate� differ-�
�ential� analog� signals� at� the� ADC’s� differential� input� pins.�
�The� AFEs� also� accept� single-ended� input� signals.� See�
�the� Configuring� for� Single-Ended� ADC� Operation� sec-�
�tion� for� details� on� how� to� modify� the� EV� kits� to� support�
�this� mode� of� operation.�
�Configuring� for� Single-Ended� ADC� Operation�
�The� MAX19710� –MAX19713� can� be� configured� to�
�accept� AC-coupled,� single-ended� signals� presented� at�
�the� input.� Configure� the� EV� kit� to� support� this� mode� of�
�operation� by� completing� the� following� steps:�
�1-2*�
�2-3�
�U2� is� powered� through� OVDD.�
�U2� is� powered� through� BVCC.�
�(Note:� BVCC� must� equal� OVDD.)�
�1)� Cut� open� the� traces� at� locations� R11–R14.�
�2)� Install� 0� Ω� resistors� at� locations� R7–R10,� R15,�
�and� R16.�
�*Default� configuration.�
�If� the� OVDD� current� is� measured� at� the� OVDD� and�
�OGND� pads� on� the� EV� kit,� a� measurement� error� occurs�
�due� to� the� extra� current� flowing� into� U2.� Power� U2�
�through� BVCC� for� a� more� accurate� measurement� of� the�
�OVDD� current� into� the� AFEs.�
�Clock�
�An� on-board� clock-shaping� circuit� generates� a� clock�
�signal� from� an� AC� sine-wave� signal� applied� to� the�
�CLOCK� SMA� connector.� The� frequency� of� the� signal�
�should� not� exceed� 45MHz� for� the� MAX19713� (see� the�
�Part� Selection� Table� for� the� maximum� sampling� rate� of�
�other� devices).� The� frequency� of� the� sinusoidal� input�
�signal� determines� the� sampling� frequency� (f� CLK� )� of� the�
�AFEs.� A� differential� line� receiver� (U3)� processes� the�
�input� signal� to� generate� the� CMOS� clock� signal.� The�
�signal’s� duty� cycle� can� be� adjusted� with� potentiometer�
�R63.� A� clock� signal� with� a� 50%� duty� cycle� (recom-�
�mended)� is� achieved� by� adjusting� R63� until� 1.32V� is�
�produced� across� test� points� TP4� and� TP5� when� the�
�3)� Install� 2k� Ω� ±1%� resistors� at� locations� R21–R24.�
�4)� Connect� the� single-ended� sources� to� the� IAP�
�connector� (I� channel)� and/or� to� the� QAP� SMA�
�connector� (Q� channel).�
�Configure� the� EV� kit� for� DC-coupled,� single-ended� sig-�
�nals� by� removing� capacitors� C1� and� C2,� removing� resis-�
�tors� R9� and� R10,� and� installing� 0� Ω� resistors� at� locations�
�R5� and� R6.�
�Tx� DAC� Outputs�
�By� default,� on-board� ultra-low-distortion� op� amps� (U4� and�
�U5)� buffer� the� DAC� outputs� on� the� MAX19710� –�
�MAX19713� EV� kits.� The� op� amps� convert� the� differential�
�signal� from� the� AFEs� to� a� single-ended� 50� Ω� signal.�
�Measure� the� buffered� output� signals� at� the� QD� SMA� con-�
�nector� (Q� channel)� and� the� ID� SMA� connector�
�(I� channel).�
�Measure� the� differential� output� of� the� AFEs� at� the�
�IDN/IDP� and� QDN/QDP� pads.� Full-scale� output,� offset�
�voltage,� and� common-mode� voltage� functions� are� con-�
�trolled� through� the� EV� kit� software.�
�8�
�_______________________________________________________________________________________�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| MAX19713EVCMODU+ | 功能描述:数据转换 IC 开发工具 MAX19710/13 Eval Kit RoHS:否 制造商:Texas Instruments 产品:Demonstration Kits 类型:ADC 工具用于评估:ADS130E08 接口类型:SPI 工作电源电压:- 6 V to + 6 V |
| MAX19713EVKIT | 功能描述:数据转换 IC 开发工具 RoHS:否 制造商:Texas Instruments 产品:Demonstration Kits 类型:ADC 工具用于评估:ADS130E08 接口类型:SPI 工作电源电压:- 6 V to + 6 V |
| MAX19713EVKIT+ | 功能描述:数据转换 IC 开发工具 MAX19710/13 Eval Kit RoHS:否 制造商:Texas Instruments 产品:Demonstration Kits 类型:ADC 工具用于评估:ADS130E08 接口类型:SPI 工作电源电压:- 6 V to + 6 V |
| MAX1971EEE | 功能描述:直流/直流开关调节器 RoHS:否 制造商:International Rectifier 最大输入电压:21 V 开关频率:1.5 MHz 输出电压:0.5 V to 0.86 V 输出电流:4 A 输出端数量: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:PQFN 4 x 5 |
| MAX1971EEE+ | 功能描述:直流/直流开关调节器 Dual 180 Out 1.4MHz 750mA Step-Down RoHS:否 制造商:International Rectifier 最大输入电压:21 V 开关频率:1.5 MHz 输出电压:0.5 V to 0.86 V 输出电流:4 A 输出端数量: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:PQFN 4 x 5 |
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