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| 型号: | MAX17004ETJ+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 33/36页 |
| 文件大小: | 0K |
| 描述: | IC PS CTRLR FOR NOTEBOOKS 32TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 应用: | 控制器,笔记本电脑电源系统 |
| 输入电压: | 6 V ~ 26 V |
| 输出数: | 4 |
| 输出电压: | 3.3V,5V,2 V ~ 5.5 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-WFQFN 裸露焊盘 |
| 供应商设备封装: | 32-TQFN-EP(5x5) |
| 包装: | 带卷 (TR) |
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�High-Efficiency,� Quad-Output,� Main� Power-�
�Supply� Controllers� for� Notebook� Computers�
�The� output� capacitor� and� the� load� resistance� create� the�
�dominant� pole� in� the� system.� However,� the� internal� ampli-�
�5)� Next,� calculate� the� zero� caused� by� the� output�
�capacitor’s� ESR:�
�fier� delay,� the� pass� transistor’s� input� capacitance,� and� the�
�stray� capacitance� at� the� feedback� node� create� additional�
�poles� in� the� system,� and� the� output� capacitor’s� ESR� gen-�
�erates� a� zero.� For� proper� operation,� use� the� following�
�f� ZERO� (� ESR� )� =�
�1�
�2� π� C� OUTA� R� ESR�
�steps� to� ensure� the� linear-regulator� stability:�
�1)� First,� calculate� the� dominant� pole� set� by� the� linear�
�regulator’s� output� capacitor� and� the� load� resistor:�
�where� R� ESR� is� the� equivalent� series� resistance� of�
�C� OUTA� .�
�6)� To� ensure� stability,� choose� C� OUTA� large� enough� so�
�f� POLE� (� LDO� )� =�
�1�
�2� π� C� OUTA� R� LOAD�
�that� the� crossover� occurs� well� before� the� poles� and�
�zero� calculated� in� steps� 2� through� 5.� The� poles� in�
�steps� 3� and� 4� generally� occur� at� several� MHz,� and�
�using� ceramic� output� capacitors� ensures� the� ESR�
�f� POLE� (� CIN� )� ≈�
�C� IN� =�
�f� POLE� (� CIN� )� ≈� T�
�f� POLE� (� FBA� )� =�
�where C� OUTA� is the output capacitance of the aux-�
�iliary� LDO� and� R� LOAD� is� the� load� resistance� corre-�
�sponding� to� the� maximum� load� current.� The� unity-�
�gain� crossover� of� the� linear� regulator� is:�
�f� CROSSOVER� =� A� V(LDO)� f� POLE(LDO)�
�2)� The� pole� caused� by� the� internal� amplifier� delay� is� at�
�approximately� 1MHz:�
�f� POLE(AMP)� ≈� 1MHz�
�3)� Next,� calculate� the� pole� set� by� the� transistor’s� input�
�capacitance,� the� transistor’s� input� resistance,� and� the�
�base-to-emitter� pullup� resistor.� Since� the� transistor’s�
�input� resistance� (h� FE� /g� m� )� is� typically� much� greater�
�than� the� base-to-emitter� pullup� resistance,� the� pole�
�can� be� determined� from� the� simplified� equation:�
�1�
�2� π� C� IN� R� IN�
�g� m�
�2� π� f� T�
�where� g� m� is� the� transconductance� of� the� pass� tran-�
�sistor,� and� f� T� is� the� transition� frequency.� Both� para-�
�meters� can� be� found� in� the� transistor’s� data� sheet.�
�Therefore,� the� equation� can� be� further� reduced� to:�
�f�
�h� FE�
�4)� Next,� calculate� the� pole� set� by� the� linear� regulator’s�
�feedback� resistance� and� the� capacitance� between�
�FBA� and� ground� (approximately� 5pF� including�
�stray� capacitance):�
�1�
�2� π� C� FBA� (� R� 5� ||� R� 6� )�
�zero� occurs� at� several� MHz� as� well.� Placing� the�
�crossover� frequency� below� 500kHz� is� typically� suf-�
�ficient� to� avoid� the� amplifier� delay� pole� and� gener-�
�ally� works� well,� unless� unusual� component�
�selection� or� extra� capacitance� moves� the� other�
�poles� or� zero� below� 1MHz.�
�A� capacitor� connected� between� the� linear� regula-�
�tor’s� output� and� the� feedback� node� can� improve�
�the� transient� response� and� reduce� the� noise� cou-�
�pled� into� the� feedback� loop.�
�If� a� low-dropout� solution� is� required,� an� external� p-�
�channel� MOSFET� pass� transistor� could� be� used.�
�However,� a� pMOS-based� linear� regulator� requires�
�higher� output� capacitance� to� stabilize� the� loop.� The�
�high� gate� capacitance� of� the� p-channel� MOSFET�
�lowers� the� f� POLE(CIN)� and� can� cause� instability.� A�
�large� output� capacitance� must� be� used� to� reduce�
�the� unity-gain� bandwidth� and� ensure� that� the� pole�
�is� well� above� the� unity-gain� crossover� frequency.�
�Applications� Information�
�Duty-Cycle� Limits�
�Minimum� Input� Voltage�
�The� minimum� input� operating� voltage� (dropout� voltage)�
�is� restricted� by� the� maximum� duty-cycle� specification�
�(see� the� Electrical� Characteristics� table).� Keep� in� mind�
�that� the� transient� performance� gets� worse� as� the� step-�
�down� regulators� approach� the� dropout� voltage,� so� bulk�
�output� capacitance� must� be� added� (see� the� voltage� sag�
�and� soar� equations� in� the� Transient� Response� section� of�
�the� SMPS� Design� Procedure� section).� The� absolute�
�point� of� dropout� occurs� when� the� inductor� current� ramps�
�down� during� the� off-time� (� Δ� I� DOWN� )� as� much� as� it� ramps�
�up� during� the� on-time� (� Δ� I� UP� ).� This� results� in� a� minimum�
�operating� voltage� defined� by� the� following� equation:�
�______________________________________________________________________________________�
�33�
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