参数资料
| 型号: | LTC3417EDHC#PBF |
| 厂商: | Linear Technology |
| 文件页数: | 15/20页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK SYNC ADJ DL 16DFN |
| 标准包装: | 73 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 2 |
| 输出电压: | 0.8 V ~ 5 V |
| 输入电压: | 2.25 V ~ 5.5 V |
| PWM 型: | 电流模式,混合 |
| 频率 - 开关: | 1.5MHz,600kHz ~ 4MHz |
| 电流 - 输出: | 800mA,1.4A |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-WFDFN 裸露焊盘 |
| 包装: | 管件 |
| 供应商设备封装: | 16-DFN(5x3) |
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�LTC3417�
�APPLICATIONS� INFORMATION�
�3)� I� 2� R� losses� are� calculated� from� the� DC� resistances� of� the�
�internal� switches,� R� SW� ,� and� the� external� inductor,� R� L� .� In�
�continuous� mode,� the� average� output� current� ?owing�
�through� inductor� L� is� “chopped”� between� the� internal�
�top� and� bottom� switches.� Thus,� the� series� resistance�
�looking� 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� OUT2� (R� SW� +� R� L� )�
�where� R� L� is� the� resistance� of� the� inductor.�
�4)� Other� “hidden”� losses� such� as� copper� trace� and� internal�
�battery� resistances� can� account� for� additional� ef?ciency�
�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� COUT� at� the� switching�
�frequency.� Other� losses� including� diode� conduction�
�losses� during� dead-time� and� inductor� core� losses� gener-�
�ally� account� for� less� than� 2%� total� additional� loss.�
�Thermal� Considerations�
�The� LTC3417� requires� the� package� Exposed� Pad� (PGND2/�
�GNDD� pin)� to� be� well� soldered� to� the� PC� board.� This� gives�
�the� DFN� and� TSSOP� packages� exceptional� thermal� proper-�
�ties,� compared� to� similar� packages� of� this� size,� making� it�
�dif?cult� in� normal� operation� to� exceed� the� maximum� junc-�
�tion� temperature� of� the� part.� In� a� majority� of� applications,�
�the� LTC3417� does� not� dissipate� much� heat� due� to� its� high�
�ef?ciency.� However,� in� applications� where� the� LTC3417� is�
�running� at� high� ambient� temperature� with� low� supply� volt-�
�age� and� high� duty� cycles,� such� as� in� dropout,� the� heat� dis-�
�sipated� may� exceed� the� maximum� junction� temperature� of�
�the� part.� If� the� junction� temperature� reaches� approximately�
�150°C,� both� switches� in� both� regulators� will� be� turned� off�
�and� the� SW� nodes� will� become� high� impedance.�
�To� prevent� the� LTC3417� from� exceeding� its� 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�
�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.�
�The� junction� temperature,� T� J� ,� is� given� by:�
�T� J� =� T� RISE� +� T� AMBIENT�
�As� an� example,� consider� the� case� when� the� LTC3417� is�
�in� dropout� in� both� regulators� at� an� input� voltage� of� 3.3V�
�with� load� currents� of� 1.4A� and� 800mA.� From� the� Typical�
�Performance� Characteristics� graph� of� Switch� Resistance,�
�the� R� DS(ON)� resistance� of� the� 1.4A� P-channel� switch� is�
�0.09Ω� and� the� R� DS(ON)� of� the� 800mA� P-channel� switch�
�is� 0.163Ω.� The� power� dissipated� by� the� part� is:�
�PD� =� I� 12� ?� R� DS(ON)1� +� I� 22� ?� R� DS(ON)2�
�PD� =� 1.4� 2� ?� 0.09� +� 0.8� 2� ?� 0.163�
�PD� =� 281mW�
�The� DFN� package� junction-to-ambient� thermal� resistance,�
�θ� JA� ,� is� about� 43°C/W.� Therefore,� the� junction� temperature�
�of� the� regulator� operating� in� a� 70°C� ambient� temperature�
�is� approximately:�
�T� J� =� 0.281� ?� 43� +� 70�
�T� J� =� 82.1°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.�
�3417fd�
�15�
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