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| 型号: | ADUM6202ARWZ |
| 厂商: | Analog Devices Inc |
| 文件页数: | 19/28页 |
| 文件大小: | 0K |
| 描述: | ISOLAT DGTL 5KVRMS 2CH 16SOIC-W |
| 标准包装: | 47 |
| 系列: | IsoPower®, iCoupler® |
| 输入 - 1 侧/2 侧: | 0/2 |
| 通道数: | 2 |
| 电源电压: | 3.3V,5V |
| 电压 - 隔离: | 5000Vrms |
| 数据速率: | 1Mbps |
| 传输延迟: | 100ns |
| 输出类型: | 逻辑 |
| 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 |
| 工作温度: | -40°C ~ 105°C |
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�Data� Sheet�
�With� a� slow� V� DD1� slew� rate� (in� the� millisecond� range),� the� input�
�voltage� is� not� changing� quickly� when� V� DD1� reaches� the� UVLO�
�minimum� voltage.� The� current� surge� is� approximately� 300� mA�
�because� V� DD1� is� nearly� constant� at� the� 2.7� V� UVLO� voltage.� The�
�behavior� during� startup� is� similar� to� when� the� device� load� is� a�
�short� circuit;� these� values� are� consistent� with� the� short-circuit�
�current� shown� in� Figure� 12.�
�When� starting� the� device� for� V� ISO� =� 5� V� operation,� do� not� limit�
�the� current� available� to� the� V� DD1� power� pin� to� less� than� 300� mA.�
�The� ADuM620x� devices� may� not� be� able� to� drive� the� output� to�
�the� regulation� point� if� a� current-limiting� device� clamps� the� V� DD1�
�voltage� during� startup.� As� a� result,� the� ADuM620x� devices� can�
�draw� large� amounts� of� current� at� low� voltage� for� extended�
�periods� of� time.�
�The� output� voltage� of� the� ADuM620x� devices� exhibits� V� ISO�
�overshoot� during� startup.� If� this� overshoot� could� potentially�
�damage� components� attached� to� V� ISO� ,� a� voltage-limiting� device�
�such� as� a� Zener� diode� can� be� used� to� clamp� the� voltage.� Typical�
�behavior� is� shown� in� Figure� 17� and� Figure� 18.�
�EMI� CONSIDERATIONS�
�The� dc-to-dc� converter� section� of� the� ADuM620x� devices� must�
�operate� at� 180� MHz� to� allow� efficient� power� transfer� through� the�
�small� transformers.� This� creates� high� frequency� currents� that� can�
�propagate� in� circuit� board� ground� and� power� planes,� causing�
�edge� emissions� and� dipole� radiation� between� the� primary� and�
�secondary� ground� planes.� Grounded� enclosures� are� recommended�
�for� applications� that� use� these� devices.� If� grounded� enclosures�
�are� not� possible,� follow� good� RF� design� practices� in� the� layout�
�of� the� PCB.� See� the� AN-0971� Application� Note� for� board� layout�
�recommendations.�
�PROPAGATION� DELAY� PARAMETERS�
�Propagation� delay� is� a� parameter� that� describes� the� time� it� takes�
�a� logic� signal� to� propagate� through� a� component.� The� propagation�
�delay� to� a� logic� low� output� may� differ� from� the� propagation�
�delay� to� a� logic� high� output.�
�ADuM6200/ADuM6201/ADuM6202�
�DC� CORRECTNESS� AND� MAGNETIC� FIELD�
�IMMUNITY�
�Positive� and� negative� logic� transitions� at� the� isolator� input�
�cause� narrow� (~1� ns)� pulses� to� be� sent� to� the� decoder� via� the�
�transformer.� The� decoder� is� bistable� and� is,� therefore,� either� set�
�or� reset� by� the� pulses,� indicating� input� logic� transitions.� In� the�
�absence� of� logic� transitions� at� the� input� for� more� than� 1� μs,� a�
�periodic� set� of� refresh� pulses� indicative� of� the� correct� input� state�
�is� sent� to� ensure� dc� correctness� at� the� output.� If� the� decoder�
�receives� no� internal� pulses� for� more� than� approximately� 5� μs,� the�
�input� side� is� assumed� to� be� unpowered� or� nonfunctional,� and�
�the� isolator� output� is� forced� to� a� default� state� by� the� watchdog�
�timer� circuit.�
�The� limitation� on� the� magnetic� field� immunity� of� the� ADuM620x�
�is� set� by� the� condition� in� which� induced� voltage� in� the� receiving�
�coil� of� the� transformer� is� sufficiently� large� to� either� falsely� set� or�
�reset� the� decoder.� The� following� analysis� defines� the� conditions�
�under� which� this� may� occur.� The� 3.3� V� operating� condition� of� the�
�ADuM620x� is� examined� because� it� represents� the� most� suscep-�
�tible� mode� of� operation.�
�The� pulses� at� the� transformer� output� have� an� amplitude� greater�
�than� 1.0� V.� The� decoder� has� a� sensing� threshold� at� approximately�
�0.5� V,� thus� establishing� a� 0.5� V� margin� in� which� induced� voltages�
�can� be� tolerated.� The� voltage� induced� across� the� receiving� coil� is�
�given� by�
�V� =� (� ?dβ/dt� )� ∑� π� r� n� 2� ;� n� =� 1,� 2,� …� ,� N�
�where:�
�β� is� the� magnetic� flux� density� (gauss).�
�r� n� is� the� radius� of� the� n� th� turn� in� the� receiving� coil� (cm).�
�N� is� the� total� number� of� turns� in� the� receiving� coil.�
�Given� the� geometry� of� the� receiving� coil� in� the� ADuM620x� and�
�an� imposed� requirement� that� the� induced� voltage� be,� at� most,�
�50%� of� the� 0.5� V� margin� at� the� decoder,� a� maximum� allowable�
�magnetic� field� is� calculated� as� shown� in� Figure� 25.�
�100�
�INPUT� (V� Ix� )�
�50%�
�OUTPUT� (V� Ox� )�
�t� PLH�
�t� PHL�
�50%�
�10�
�1�
�Figure� 24.� Propagation� Delay� Parameters�
�Pulse� width� distortion� is� the� maximum� difference� between�
�these� two� propagation� delay� values� and� is� an� indication� of� how�
�accurately� the� timing� of� the� input� signal� is� preserved.�
�Channel-to-channel� matching� refers� to� the� maximum� amount�
�0.1�
�0.01�
�that� the� propagation� delay� differs� between� channels� within� a�
�single� ADuM620x� component.�
�0.001�
�1k�
�10k� 100k� 1M� 10M�
�MAGNETIC� FIELD� FREQUENCY� (Hz)�
�100M�
�Propagation� delay� skew� refers� to� the� maximum� amount� that�
�the� propagation� delay� differs� between� multiple� ADuM620x�
�components� operating� under� the� same� conditions.�
�Rev.� C� |� Page� 19� of� 28�
�Figure� 25.� Maximum� Allowable� External� Magnetic� Flux� Density�
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| ADUM6202ARWZ-RL | 功能描述:隔离器接口集成电路 5kV 2-Ch Isolator w/ Int DC/DC Converter RoHS:否 制造商:Texas Instruments 通道数量:2 传播延迟时间: 电源电压-最大:5.5 V 电源电压-最小:3 V 电源电流:3.6 mA 功率耗散: 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:SOIC-8 封装:Tube |
| ADUM6202CRIZ | 功能描述:ISOLATED DC-DC CONV 2CH 16SOIC RoHS:是 类别:隔离器 >> 数字隔离器 系列:IsoPower®, iCoupler® 产品培训模块:IsoLoop® Isolator 标准包装:50 系列:IsoLoop® 输入 - 1 侧/2 侧:5/0 通道数:5 电源电压:3 V ~ 5.5 V 电压 - 隔离:2500Vrms 数据速率:110Mbps 传输延迟:12ns 输出类型:CMOS 封装/外壳:16-SOIC(0.154",3.90mm 宽) 供应商设备封装:16-SOIC N 包装:管件 工作温度:-40°C ~ 85°C 其它名称:390-1053-5 |
| ADUM6202CRIZ-RL | 功能描述:IC ISOLATOR DGTL 2CH 16SOIC RoHS:是 类别:隔离器 >> 数字隔离器 系列:IsoPower®, iCoupler® 产品培训模块:IsoLoop® Isolator 标准包装:50 系列:IsoLoop® 输入 - 1 侧/2 侧:5/0 通道数:5 电源电压:3 V ~ 5.5 V 电压 - 隔离:2500Vrms 数据速率:110Mbps 传输延迟:12ns 输出类型:CMOS 封装/外壳:16-SOIC(0.154",3.90mm 宽) 供应商设备封装:16-SOIC N 包装:管件 工作温度:-40°C ~ 85°C 其它名称:390-1053-5 |
| ADUM6202CRWZ | 功能描述:ISOLAT DGTL 5KVRMS 2CH 16SOIC-W RoHS:是 类别:隔离器 >> 数字隔离器 系列:IsoPower®, iCoupler® 产品培训模块:IsoLoop® Isolator 标准包装:50 系列:IsoLoop® 输入 - 1 侧/2 侧:5/0 通道数:5 电源电压:3 V ~ 5.5 V 电压 - 隔离:2500Vrms 数据速率:110Mbps 传输延迟:12ns 输出类型:CMOS 封装/外壳:16-SOIC(0.154",3.90mm 宽) 供应商设备封装:16-SOIC N 包装:管件 工作温度:-40°C ~ 85°C 其它名称:390-1053-5 |
| ADUM6202CRWZ-RL | 功能描述:隔离器接口集成电路 5kV 2-Ch Isolator w/ Int DC/DC Converter RoHS:否 制造商:Texas Instruments 通道数量:2 传播延迟时间: 电源电压-最大:5.5 V 电源电压-最小:3 V 电源电流:3.6 mA 功率耗散: 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:SOIC-8 封装:Tube |
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