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| 型号: | ADP121CB-3.3-EVALZ |
| 厂商: | Analog Devices Inc |
| 文件页数: | 14/20页 |
| 文件大小: | 0K |
| 描述: | BOARD EVAL ADP121-1 3.3V OUTPUT |
| 设计资源: | Low power, Long Range, ISM Wireless Measuring Node (CN0164) |
| 标准包装: | 1 |
| 每 IC 通道数: | 1 - 单 |
| 输出电压: | 3.3V |
| 电流 - 输出: | 150mA |
| 输入电压: | 2.3 ~ 5.5 V |
| 稳压器类型: | 正,固定式 |
| 工作温度: | -40°C ~ 125°C |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | ADP121 |
��
�
�ADP121�
�CURRENT� LIMIT� AND� THERMAL� OVERLOAD�
�PROTECTION�
�The� ADP121� is� protected� against� damage� due� to� excessive�
�power� dissipation� by� current� and� thermal� overload� protection�
�circuits.� The� ADP121� is� designed� to� current� limit� when� the�
�output� load� reaches� 225� mA� (typical).� When� the� output� load�
�Data� Sheet�
�dissipation� in� the� power� device,� and� thermal� resistances� between�
�the� junction-and-ambient� air� (θ� JA� ).� The� θ� JA� number� is� dependent�
�on� the� package� assembly� compounds� used� and� the� amount� of�
�copper� to� which� the� GND� pins� of� the� package� are� soldered� on� the�
�PCB.� Table� 6� shows� typical� θ� JA� values� for� various� PCB� copper�
�sizes� and� Table� 7� shows� the� typical� Ψ� JB� values� for� the� ADP121.�
�exceeds� 225� mA,� the� output� voltage� is� reduced� to� maintain� a�
�constant� current� limit.�
�Table� 6.� Typical� θ� JA� Values�
�Copper� Size� (mm� 2� )� TSOT� (°C/W)�
�WLCSP� (°C/W)�
�Thermal� overload� protection� is� built-in,� which� limits� the�
�junction� temperature� to� a� maximum� of� 150°C� (typical).� Under�
�extreme� conditions� (that� is,� high� ambient� temperature� and�
�power� dissipation)� when� the� junction� temperature� starts� to�
�rise� above� 150°C,� the� output� is� turned� off,� reducing� the� output�
��50�
�100�
�300�
�500�
�170�
�152�
�146�
�134�
�131�
�260�
�159�
�157�
�153�
�151�
�current� to� zero.� When� the� junction� temperature� drops� below�
�135°C,� the� output� is� turned� on� again� and� output� current� is�
�1�
�Device� soldered� to� minimum� size� pin� traces.�
�restored� to� its� nominal� value.�
�Table� 7.� Typical� Ψ� JB� Values�
�Consider� the� case� where� a� hard� short� from� VOUT� to� GND� occurs.�
�At� first,� the� ADP121� current� limits,� so� that� only� 225� mA� is� con-�
�TSOT� (°C/W)�
�42.8�
�WLCSP� (°C/W)�
�58.4�
�ducted� into� the� short.� If� self-heating� of� the� junction� is� great�
�enough� to� cause� its� temperature� to� rise� above� 150°C,� thermal�
�shutdown� activates� turning� off� the� output� and� reducing� the�
�The� junction� temperature� of� the� ADP121� can� be� calculated�
�from� the� following� equation:�
�output� current� to� zero.� As� the� junction� temperature� cools� and�
�drops� below� 135°C,� the� output� turns� on� and� conducts� 225� mA�
�into� the� short,� again� causing� the� junction� temperature� to� rise�
�above� 150°C.� This� thermal� oscillation� between� 135°C� and�
�150°C� causes� a� current� oscillation� between� 225� mA� and� 0� mA�
�that� continues� as� long� as� the� short� remains� at� the� output.�
�T� J� =� T� A� +� (� P� D� ×� θ� JA� )�
�where:�
�T� A� is� the� ambient� temperature.�
�P� D� is� the� power� dissipation� in� the� die,� given� by�
�P� D� =� [(� V� IN� ?� V� OUT� )� � I� LOAD� ]� +� (� V� IN� � I� GND� )�
�(2)�
�(3)�
�Current� and� thermal� limit� protections� are� intended� to� protect�
�the� device� against� accidental� overload� conditions.� For� reliable�
�operation,� device� power� dissipation� must� be� externally� limited�
�so� junction� temperatures� do� not� exceed� 125°C.�
�THERMAL� CONSIDERATIONS�
�In� most� applications,� the� ADP121� does� not� dissipate� a� lot� of� heat�
�due� to� high� efficiency.� However,� in� applications� with� a� high�
�ambient� temperature� and� high� supply� voltage� to� an� output� voltage�
�differential,� the� heat� dissipated� in� the� package� is� large� enough�
�that� it� can� cause� the� junction� temperature� of� the� die� to� exceed�
�the� maximum� junction� temperature� of� 125°C.�
�When� the� junction� temperature� exceeds� 150°C,� the� converter�
�enters� thermal� shutdown.� It� recovers� only� after� the� junction�
�temperature� has� decreased� below� 135°C� to� prevent� any� permanent�
�damage.� Therefore,� thermal� analysis� for� the� chosen� application�
�is� very� important� to� guarantee� reliable� performance� over� all�
�conditions.� The� junction� temperature� of� the� die� is� the� sum� of�
�the� ambient� temperature� of� the� environment� and� the� tempera-�
�ture� rise� of� the� package� due� to� the� power� dissipation,� as� shown�
�where:�
�I� LOAD� is� the� load� current.�
�I� GND� is� the� ground� current.�
�V� IN� and� V� OUT� are� input� and� output� voltages,� respectively.�
�Power� dissipation� due� to� ground� current� is� quite� small� and�
�can� be� ignored.� Therefore,� the� junction� temperature� equation�
�simplifies� to�
�T� J� =� T� A� +� {[(� V� IN� ?� V� OUT� )� ×� I� LOAD� ]� ×� θ� JA� }� (4)�
�As� shown� in� Equation� 4,� for� a� given� ambient� temperature,�
�input-to-output� voltage� differential,� and� continuous� load�
�current,� there� exists� a� minimum� copper� size� requirement� for�
�the� PCB� to� ensure� that� the� junction� temperature� does� not� rise�
�above� 125°C.� Figure� 34� to� Figure� 47� show� junction� temperature�
�calculations� for� different� ambient� temperatures,� load� currents,�
�V� IN� -to-V� OUT� differentials,� and� areas� of� PCB� copper.�
�In� cases� where� the� board� temperature� is� known,� the� thermal�
�characterization� parameter,� Ψ� JB� ,� can� be� used� to� estimate� the�
�junction� temperature� rise.� T� J� is� calculated� from� T� B� and� P� D� using�
�the� formula�
�in� Equation� 2.�
�To� guarantee� reliable� operation,� the� junction� temperature� of� the�
�ADP121� must� not� exceed� 125°C.� To� ensure� that� the� junction�
�temperature� stays� below� this� maximum� value,� the� user� needs� to�
�be� aware� of� the� parameters� that� contribute� to� junction� temperature�
�changes.� These� parameters� include� ambient� temperature,� power�
�Rev.� G� |� Page� 14� of� 20�
�T� J� =� T� B� +� (� P� D� ×� Ψ� JB� )�
�(5)�
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