参数资料
| 型号: | LTC3411AIMS#TRPBF |
| 厂商: | Linear Technology |
| 文件页数: | 16/22页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK SYNC ADJ 10MSOP |
| 标准包装: | 2,500 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 0.8 V ~ 5 V |
| 输入电压: | 2.5 V ~ 5.5 V |
| PWM 型: | 电流模式,混合 |
| 频率 - 开关: | 2.5MHz |
| 电流 - 输出: | 1.25A |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 10-TFSOP,10-MSOP(0.118",3.00mm 宽) |
| 包装: | 带卷 (TR) |
| 供应商设备封装: | 10-MSOP |
��
�
�LTC3411A�
�APPLICATIONS� INFORMATION�
�L� =�
�?� ?� 1� ?�
�?� =� 2� μ� H�
�3)� I� 2� R� Losses� are� calculated� from� the� DC� resistances� of�
�the� internal� switches,� R� SW� ,� and� external� inductor,� R� L� .� In�
�continuous� mode,� the� average� output� current� flowing�
�through� inductor� L� is� “chopped”� between� the� internal� top�
�and� bottom� switches.� Thus,� the� series� resistance� look-�
�ing� into� the� SW� pin� is� a� function� of� both� top� and� bottom�
�MOSFET� R� DS(ON)� and� the� duty� cycle� (DC)� as� follows:�
�R� SW� =� (R� DS(ON)� TOP)(DC)� +� (R� DS(ON)� BOT)(1� –� DC)�
�The� R� DS(ON)� for� both� the� top� and� bottom� MOSFETs� can�
�be� obtained� from� the� Typical� Performance� Characteristics�
�curves.� Thus,� to� obtain� I� 2� R� losses:�
�I� 2� R� losses� =� I� OUT� 2(R� SW� +� R� L� )�
�4)� Other� “hidden”� losses� such� as� copper� trace� and� internal�
�battery� resistances� can� account� for� additional� efficiency�
�degradations� in� portable� systems.� It� is� very� important�
�to� include� these� “system”� level� losses� in� the� design� of� a�
�system.� The� internal� battery� and� fuse� resistance� losses� can�
�be� minimized� by� making� sure� that� C� IN� has� adequate� charge�
�storage� and� very� low� ESR� at� the� switching� frequency.� Other�
�losses� including� diode� conduction� losses� during� dead-time�
�and� inductor� core� losses� which� generally� account� for� less�
�than� 2%� total� additional� loss.�
�Thermal� Considerations�
�In� a� majority� of� applications,� the� LTC3411A� does� not�
�dissipate� much� heat� due� to� its� high� efficiency.� However,�
�in� applications� where� the� LTC3411A� is� running� at� high�
�ambient� temperature� with� low� supply� voltage� and� high�
�duty� cycles,� such� as� in� dropout,� the� heat� dissipated� may�
�exceed� the� maximum� junction� temperature� of� the� part.� If�
�the� junction� temperature� reaches� approximately� 150°C,�
�both� power� switches� will� be� turned� off� and� the� SW� node�
�will� become� high� impedance.�
�To� avoid� the� LTC3411A� from� exceeding� the� maximum� junc-�
�tion� temperature,� the� user� will� need� to� do� some� thermal�
�analysis.� The� goal� of� the� thermal� analysis� is� to� determine�
�whether� the� power� dissipated� exceeds� the� maximum� junction�
�temperature� of� the� part.� The� temperature� rise� is� given� by:�
�T� RISE� =� P� D� ?� θ� JA�
�The� junction� temperature,� T� J� ,� is� given� by:�
�T� J� =� T� RISE� +� T� AMBIENT�
�As� an� example,� consider� the� case� when� the� LTC3411A�
�is� in� dropout� at� an� input� voltage� of� 3.3V� with� a� load� cur-�
�rent� of� 1A.� From� the� Typical� Performance� Characteristics�
�graph� of� Switch� Resistance,� the� R� DS(ON)� resistance� of� the�
�P-channel� switch� is� 0.15Ω.� Therefore,� power� dissipated�
�by� the� part� is:�
�P� D� =� I� 2� ?� R� DS(ON)� =� 150mW�
�The� MS10� package� junction-to-ambient� thermal� resistance,�
�θ� JA� ,� will� be� in� the� range� of� 100°C/W� to� 120°C/W.� Therefore,�
�the� junction� temperature� of� the� regulator� operating� in� a�
�70°C� ambient� temperature� is� approximately:�
�T� J� =� 0.15� ?� 120� +� 70� =� 88°C�
�Remembering� that� the� above� junction� temperature� is�
�obtained� from� an� R� DS(ON)� at� 25°C,� we� might� recalculate�
�the� junction� temperature� based� on� a� higher� R� DS(ON)� since�
�it� increases� with� temperature.� However,� we� can� safely� as-�
�sume� that� the� actual� junction� temperature� will� not� exceed�
�the� absolute� maximum� junction� temperature� of� 125°C.�
�Design� Example�
�As� a� design� example,� consider� using� the� LTC3411A� in� a�
�portable� application� with� a� Li-Ion� battery.� The� battery� pro-�
�vides� a� V� IN� =� 2.5V� to� 4.2V.� The� load� requires� a� maximum�
�of� 1.25A� in� active� mode� and� 10mA� in� standby� mode.� The�
�output� voltage� is� V� OUT� =� 2.5V.� Since� the� load� still� needs�
�power� in� standby,� Burst� Mode� operation� is� selected� for�
�good� low� load� efficiency.�
�First,� calculate� the� timing� resistor� for� 1MHz� operation:�
�R� T� =� 5� ?� 10� 7� (10� 3� )� –1.6508� =� 557.9k�
�Use� a� standard� value� of� 549k.� Next,� calculate� the� inductor�
�value� for� about� 40%� ripple� current� at� maximum� V� IN� :�
�2.5V� ?� 2.5V� ?�
�1MHz� ?� 500mA� ?� 4.2V� ?�
�Choosing� the� closest� standard� inductor� value� from� a� vendor�
�of� 2.2μH,� results� in� a� maximum� ripple� current� of:�
�?� ?� 1� ?�
�where� P� D� is� the� power� dissipated� by� the� regulator� and� θ� JA�
�is� the� thermal� resistance� from� the� junction� of� the� die� to�
�the� ambient� temperature.�
�Δ� I� L� =�
�2.5V�
�1MHz� ?� 2.2� μ�
�?�
�?�
�2.5V� ?�
�4.2V� ?� ?�
�=� 460mA�
�3411afc�
�16�
�For� more� information� www.linear.com/LTC3411A�
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参数描述 |
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| LTC3411EDD#TR | 功能描述:IC REG BUCK SYNC ADJ 1.25A 10DFN RoHS:否 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 开关稳压器 系列:- 标准包装:2,500 系列:- 类型:降压(降压) 输出类型:固定 输出数:1 输出电压:1.2V,1.5V,1.8V,2.5V 输入电压:2.7 V ~ 20 V PWM 型:- 频率 - 开关:- 电流 - 输出:50mA 同步整流器:是 工作温度:-40°C ~ 125°C 安装类型:表面贴装 封装/外壳:10-TFSOP,10-MSOP(0.118",3.00mm 宽)裸露焊盘 包装:带卷 (TR) 供应商设备封装:10-MSOP 裸露焊盘 |
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