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| 型号: | ISL6441IR-T |
| 厂商: | Intersil |
| 文件页数: | 16/18页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR PWM DUAL 1.4MHZ 28-QFN |
| 标准包装: | 6,000 |
| 应用: | 电源 |
| 电流 - 电源: | 2mA |
| 电源电压: | 5.6 V ~ 24 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-VFQFN 裸露焊盘 |
| 供应商设备封装: | 28-QFN 裸露焊盘(5x5) |
| 包装: | 带卷 (TR) |
��
�
�ISL6441�
�The� power� dissipation� includes� two� loss� components;�
�conduction� loss� and� switching� loss.� These� losses� are�
�distributed� between� the� upper� and� lower� MOSFETs�
�according� to� duty� cycle� (see� Equations� 10� and� 11).� The�
�conduction� losses� are� the� main� component� of� power�
�dissipation� for� the� lower� MOSFETs.� Only� the� upper� MOSFET�
�has� significant� switching� losses,� since� the� lower� device� turns�
�on� and� off� into� near� zero� voltage.� Equations� 10� and� 11�
�assume� linear� voltage-current� transitions� and� do� not� model�
�power� loss� due� to� the� reverse-recovery� of� the� lower�
�MOSFET’s� body� diode.�
�is� the� input� voltage,� V� O� is� output� voltage,� and� DV� OUT� is� the�
�drop� in� output� voltage� allowed� during� the� load� transient.�
�High� frequency� capacitors� initially� supply� the� transient�
�current� and� slow� the� load� rate-of-change� seen� by� the� bulk�
�capacitors.� The� bulk� filter� capacitor� values� are� generally�
�determined� by� the� ESR� (Equivalent� Series� Resistance)� and�
�voltage� rating� requirements� as� well� as� actual� capacitance�
�requirements.�
�The� output� voltage� ripple� is� due� to� the� inductor� ripple� current�
�and� the� ESR� of� the� output� capacitors� as� defined� by�
�(� I� O� )� (� r� DS� (� ON� )� )� (� V� OUT� )�
�(� I� O� )� (� V� IN� )� (� t� SW� )� (� F� SW� )�
�P� UPPER� =� ---------------------------------------------------------------� +� ------------------------------------------------------------�
�V� IN�
�(EQ.� 10)�
�2�
�2�
�Equation� 13.�
�V� RIPPLE� =� Δ� I� L� (� ESR� )�
�(EQ.� 13)�
�(� I� O� )� (� r� DS� (� ON� )� )� (� V� IN� –� V� OUT� )�
�P� LOWER� =� -------------------------------------------------------------------------------�
�2�
�V� IN�
�(EQ.� 11)�
�where,� I� L� is� calculated� in� the� “Output� Inductor� Selection”� on�
�page� 17.�
�High� frequency� decoupling� capacitors� should� be� placed� as�
�A� large� gate-charge� increases� the� switching� time,� t� SW� ,�
�which� increases� the� upper� MOSFET� switching� losses.�
�Ensure� that� both� MOSFETs� are� within� their� maximum�
�junction� temperature� at� high� ambient� temperature� by�
�calculating� the� temperature� rise� according� to� package�
�thermal-resistance� specifications.�
�Output� Capacitor� Selection�
�The� output� capacitors� for� each� output� have� unique�
�requirements.� In� general,� the� output� capacitors� should� be�
�selected� to� meet� the� dynamic� regulation� requirements�
�including� ripple� voltage� and� load� transients.� Selection� of�
�output� capacitors� is� also� dependent� on� the� output� inductor,�
�so� some� inductor� analysis� is� required� to� select� the� output�
�capacitors.�
�One� of� the� parameters� limiting� the� converter� ’s� response� to� a�
�load� transient� is� the� time� required� for� the� inductor� current� to�
�close� to� the� power� pins� of� the� load� as� physically� possible.� Be�
�careful� not� to� add� inductance� in� the� circuit� board� wiring� that�
�could� cancel� the� usefulness� of� these� low� inductance�
�components.� Consult� with� the� manufacturer� of� the� load�
�circuitry� for� specific� decoupling� requirements.�
�Use� only� specialized� low-ESR� capacitors� intended� for�
�switching-regulator� applications� at� 1.4MHz� for� the� bulk�
�capacitors.� In� most� cases,� multiple� small-case� electrolytic�
�capacitors� perform� better� than� a� single� large-case� capacitor.�
�The� stability� requirement� on� the� selection� of� the� output�
�capacitor� is� that� the� ‘ESR� zero’,� f� Z� ,� be� between� 2kHz� and�
�50kHz.� This� range� is� set� by� an� internal,� single� compensation�
�zero� at� 10kHz.� The� ESR� zero� can� be� a� factor� of� five� on� either�
�side� of� the� internal� zero� and� still� contribute� to� increased�
�phase� margin� of� the� control� loop.� Therefore,� see�
�Equation� 14.�
�C� OUT� =� ------------------------------------�
�slew� to� its� new� level.� The� ISL6441� will� provide� either� 0%� or�
�71%� duty� cycle� in� response� to� a� load� transient.�
�The� response� time� is� the� time� interval� required� to� slew� the�
�1�
�2� π� (� ESR� )� (� f� Z� )�
�(EQ.� 14)�
�inductor� current� from� an� initial� current� value� to� the� load�
�current� level.� During� this� interval� the� difference� between� the�
�inductor� current� and� the� transient� current� level� must� be�
�supplied� by� the� output� capacitor(s).� Minimizing� the� response�
�time� can� minimize� the� output� capacitance� required.� Also,� if�
�the� load� transient� rise� time� is� slower� than� the� inductor�
�response� time,� as� in� a� hard� drive� or� CD� drive,� it� reduces� the�
�requirement� on� the� output� capacitor.�
�The� maximum� capacitor� value� required� to� provide� the� full,�
�rising� step,� transient� load� current� during� the� response� time� of�
�the� inductor� is� shown� in� Equation� 12:�
�In� conclusion,� the� output� capacitors� must� meet� three� criteria:�
�1.� They� must� have� sufficient� bulk� capacitance� to� sustain� the�
�output� voltage� during� a� load� transient� while� the� output�
�inductor� current� is� slewing� to� the� value� of� the� load�
�transient,�
�2.� The� ESR� must� be� sufficiently� low� to� meet� the� desired�
�output� voltage� ripple� due� to� the� output� inductor� current,�
�and�
�3.� The� ESR� zero� should� be� placed� in� a� rather� large� range,�
�to� provide� additional� phase� margin.�
�The� recommended� output� capacitor� value� for� the� ISL6441� is�
�(� L� O� )� (� I� TRAN� )�
�2� (� V� IN� –� V� O� )� (� DV� OUT� )�
�2�
�C� OUT� =� -----------------------------------------------------------�
�(EQ.� 12)�
�between� 150μF� to� 680μF,� to� meet� stability� criteria� with�
�external� compensation.� Use� of� low� ESR� ceramic� capacitors�
�is� possible� but� would� take� more� rigorous� loop� analysis� to�
�where,� C� OUT� is� the� output� capacitor(s)� required,� L� O� is� the�
�output� inductor,� I� TRAN� is� the� transient� load� current� step,� V� IN�
�16�
�ensure� stability.�
�FN9197.3�
�May� 26,� 2009�
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