参数资料
| 型号: | ADP3367ARZ |
| 厂商: | Analog Devices Inc |
| 文件页数: | 7/8页 |
| 文件大小: | 0K |
| 描述: | IC REG LDO 5V/ADJ .2A 8SOIC |
| 标准包装: | 98 |
| 稳压器拓扑结构: | 正,固定式或可调式 |
| 输出电压: | 5V,1.3 V ~ 16 V |
| 输入电压: | 2.5 V ~ 16.5 V |
| 电压 - 压降(标准): | 0.3V @ 300mA |
| 稳压器数量: | 1 |
| 电流 - 输出: | 200mA(最小值) |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 8-SOIC |
| 包装: | 管件 |
| 产品目录页面: | 795 (CN2011-ZH PDF) |
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�
�ADP3367�
�This� may� be� expressed� in� terms� of� power� dissipation� as� follows:�
�P� D� =� (� T� J� –� T� A� )/(� θ� JA� )�
�where:�
�T� J� =� Die� Junction� Temperature� (� °� C)�
�T� A� =� Ambient� Temperature� (� °� C)�
�P� D� =� Power� Dissipation� (W)�
�θ� JA� =� Junction� to� Ambient� Thermal� Resistance� (� °� C/W)�
�If� the� device� is� being� operated� at� the� maximum� permitted� ambi-�
�ent� temperature� of� 85� °� C,� the� maximum� power� dissipation� per-�
�mitted� is:�
�P� D� (max)� =� (� T� J� (� max� )� –� T� A� )/(� θ� JA� )�
�P� D� (� max� )� =� (125� –� 85)/(� θ� JA� )�
�=� 40/� θ� JA�
�where:�
�θ� JA� =� 98� °� C/W� for� the� 8-pin� SOIC� (R-8)� package�
�Therefore,� for� a� maximum� ambient� temperature� of� 85� °� C�
�P� D� (max)� =� 408� mW� for� R-� 8�
�At� lower� ambient� temperatures� the� maximum� permitted� power�
�dissipation� increases� accordingly� up� to� the� maximum� limits�
�specified� in� the� absolute� maximum� specifications.�
�The� thermal� impedance� (� θ� JA� )� figures� given� are� measured� in� still�
�air� conditions� and� are� reduced� considerably� where� fan� assisted�
�cooling� is� employed.� Other� techniques� for� reducing� the� thermal�
�impedance� include� large� contact� pads� on� the� printed� circuit�
�board� and� wide� traces.� The� copper� will� act� as� a� heat� exchanger�
�thereby� reducing� the� effective� thermal� impedance.�
�perature� differential� between� the� die� and� PC� board;� remember,�
�the� rate� at� which� heat� is� transferred� is� directly� proportional� to�
�the� temperature� differential.�
�Various� PC� board� layout� techniques� could� be� used� to� remove�
�the� heat� from� the� immediate� vicinity� of� the� package.� Consider�
�the� following� issues� when� designing� a� board� layout:�
�1.� PC� board� traces� with� larger� copper� cross� section� areas� will�
�remove� more� heat;� use� PCs� with� thicker� copper� and/or� wider�
�traces.�
�2.� Increase� the� surface� area� exposed� to� open� air� so� heat� can� be�
�removed� by� convection� or� forced� air� flow.�
�3.� Use� larger� masses� such� as� heat� sinks� or� thermally� conductive�
�enclosures� to� distribute� and� dissipate� the� heat.�
�4.� Do� not� solder� mask� or� silk� screen� the� heat� dissipating� traces;�
�black� anodizing� will� significantly� improve� heat� dissipation� by�
�means� of� increased� radiation.�
�High� Power� Dissipation� Recommendations�
�Where� excessive� power� dissipation� due� to� high� input-output�
�differential� voltages� and/or� high� current� conditions� exists,� the�
�simplest� method� of� reducing� the� power� requirements� on� the�
�regulator� is� to� use� a� series� dropper� resistor.� In� this� way� the�
�excess� power� can� be� dissipated� in� the� external� resistor.� As� an�
�example,� consider� an� input� voltage� of� +12� V� and� an� output�
�voltage� requirement� of� +5� V� @� 100� mA� with� an� ambient� tem-�
�perature� of� +85� °� C.� The� package� power� dissipation� under� these�
�conditions� is� 700� mW� which� exceeds� the� maximum� ratings.� By�
�using� a� dropper� resistor� to� drop� 4� V,� the� power� dissipation�
�requirement� for� the� regulator� is� reduced� to� 300� mW� which� is�
�within� the� maximum� specifications� for� the� SO-8� package� at�
�85� °� C.� The� resistor� value� is� calculated� as� R� =� 4/0.1� =� 40� ?� .� A�
�resistor� power� rating� of� 1/2� W� or� greater� may� be� used.�
�POWER� DISSIPATION�
�Low� Thermal� Resistance� Package�
�The� ADP3367� utilizes� a� patented� and� proprietary� Thermal�
�Coastline� Leadframe� which� offers� significantly� lower� resistance�
�to� heat� flow� from� die� to� the� PC� board.�
�V� IN�
�12V�
�40� ?�
�0.5W�
�C1�
�1μF�
�+�
�IN�
�OUT�
�ADP3367�
�+�
�C2�
�10μF�
�+5V�
�OUTPUT�
�Heat� generated� on� the� die� is� removed� and� transferred� to� the� PC�
�SET� GND� SHDN�
�board� faster� resulting� in� lower� die� temperature� than� standard�
�packages.� Table� II� is� a� performance� comparison� between� and�
�standard� and� Thermal� Coastline� package.�
�Figure� 14.� Reducing� Regulator� Power� Dissipation�
�Table� I.� Thermal� Resistance� Performance� Comparison*�
�Transient� Response�
�θ� JC�
�θ� JA�
�PD�
�Standard� Package� (SO-8)�
�44� °� C/W�
�170� °� C/W�
�235� mW�
�Thermal� Coastline� Package�
�40� °� C/W�
�98� °� C/W�
�408� mW�
�The� ADP3367� exhibits� excellent� transient� performance� as� illus-�
�trated� in� the� “Typical� Performance� Characteristics.”� Figure� 6�
�shows� that� an� input� step� from� 10� V� to� 6� V� results� in� a� very� small�
�output� disturbance� (50� mV).� Adding� an� input� capacitor� would�
�improve� this� even� more.�
�*Data� presented� in� Table� II� is� obtained� using� SEMI� Standard� Method� G38-47�
�and� SEMI� Standard� Specification� G42-88.�
�A� device� operating� at� room� temperature,� +25� °� C,� and� +125� °� C�
�junction� temperature� can� dissipate� 1.15� W.�
�To� maintain� this� high� level� of� heat� removal� efficiency,� once� heat�
�is� removed� from� the� die� to� the� PC� board,� it� should� be� dissipated�
�to� the� air� or� other� mediums� to� maintain� the� largest� possible� tem-�
�REV.� A� 0�
�–7� –�
�Figure� 7� shows� how� quickly� the� regulator� recovers� from� an� out-�
�put� load� change� from� 10� mA� to� 100� mA.� The� offset� due� to� the�
�load� current� change� is� less� than� 1� mV.�
�Monitored� μ� P� Power� Supply�
�Figure� 15� shows� the� ADP3367� being� used� in� a� monitored� μ� P�
�supply� application.� The� ADP3367� supplies� +5� V� for� the� micro-�
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相关代理商/技术参数 |
参数描述 |
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| ADP3367ARZ | 制造商:Analog Devices 功能描述:LDO 2.5-16.5V 0.3VDO 0.3A 8SOIC |
| ADP3367ARZ-REEL | 制造商:Analog Devices 功能描述:LDO Regulator Pos 1.3V to 16V5V 0.2A 8-Pin SOIC N T/R |
| ADP3367ARZ-REEL7 | 功能描述:IC REG LDO 5V/ADJ .2A 8SOIC RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - 线性 系列:- 标准包装:800 系列:- 稳压器拓扑结构:正,固定式 输出电压:2.5V 输入电压:最高 16V 电压 - 压降(标准):0.7V @ 4A 稳压器数量:1 电流 - 输出:4A 电流 - 限制(最小):4.2A 工作温度:0°C ~ 125°C 安装类型:表面贴装 封装/外壳:TO-263-6,D²Pak(5 引线+接片),TO-263BA 供应商设备封装:TO-263-5 包装:带卷 (TR) 其它名称:AP1184K525L-13AP1184K525LDITR |
| ADP3401 | 制造商:AD 制造商全称:Analog Devices 功能描述:GSM Power Management System |
| ADP3401ARU | 制造商:AD 制造商全称:Analog Devices 功能描述:GSM Power Management System |
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