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参数资料
| 型号: | ISL9440CEVAL1Z |
| 厂商: | Intersil |
| 文件页数: | 21/24页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD 1 FOR ISL9440C |
| 产品培训模块: | Solutions for Industrial Control Applications |
| 标准包装: | 1 |
| 系列: | * |
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�ISL9440B,� ISL9440C�
�The� linear� regulator� output� can� be� supplied� by� the� output� of�
�one� of� the� PWMs.� When� using� a� PFET,� the� output� of� the�
�linear� regulator� will� track� the� PWM� supply� after� the� PWM�
�output� rises� to� a� voltage� greater� than� the� threshold� of� the�
�PFET� pass� device.� The� voltage� differential� between� the�
�PWM� and� the� linear� output� will� be� the� load� current� times� the�
�r� DS(ON)� .�
�Base-Drive� Noise� Reduction�
�The� high-impedance� base� driver� is� susceptible� to� system�
�noise,� especially� when� the� linear� regulator� is� lightly� loaded.�
�Capacitively� coupled� switching� noise� or� inductively� coupled�
�EMI� onto� the� base� drive� causes� fluctuations� in� the� base�
�current,� which� appear� as� noise� on� the� linear� regulator� ’s�
�output.� Keep� the� base� drive� traces� away� from� the� step-down�
�converter,� and� as� short� as� possible,� to� minimize� noise�
�coupling.� A� resistor� in� series� with� the� gate� drivers� reduces�
�the� switching� noise� generated� by� PWM.� Additionally,� a�
�bypass� capacitor� may� be� placed� across� the� base-to-emitter�
�resistor.� This� bypass� capacitor,� in� addition� to� the� transistor� ’s�
�input� capacitor,� could� bring� in� a� second� pole� that� will�
�destabilize� the� linear� regulator.� Therefore,� the� stability�
�requirements� determine� the� maximum� base-to-emitter�
�capacitance.�
�Layout� Guidelines�
�Careful� attention� to� layout� requirements� is� necessary� for�
�successful� implementation� of� an� ISL9440B� and� ISL9440C�
�based� DC/DC� converter.� The� ISL9440B� and� ISL9440C�
�switch� at� a� very� high� frequency� and� therefore,� the� switching�
�times� are� very� short.� At� these� switching� frequencies,� even�
�the� shortest� trace� has� significant� impedance.� Also,� the� peak�
�gate� drive� current� rises� significantly� in� an� extremely� short�
�time.� Transition� speed� of� the� current� from� one� device� to�
�another� causes� voltage� spikes� across� the� interconnecting�
�impedances� and� parasitic� circuit� elements.� These� voltage�
�spikes� can� degrade� efficiency,� generate� EMI,� increase�
�device� overvoltage� stress� and� ringing.� Careful� component�
�selection� and� proper� PC� board� layout� minimizes� the�
�magnitude� of� these� voltage� spikes.�
�There� are� three� sets� of� critical� components� in� a� DC/DC�
�converter� using� the� ISL9440B� and� ISL9440C:� the� controller,�
�the� switching� power� components� and� the� small� signal�
�components.� The� switching� power� components� are� the� most�
�critical� from� a� layout� point� of� view� because� they� switch� a�
�large� amount� of� energy� so� they� tend� to� generate� a� large�
�amount� of� noise.� The� critical� small� signal� components� are�
�those� connected� to� sensitive� nodes� or� those� supplying�
�critical� bias� currents.� A� multi-layer� printed� circuit� board� is�
�recommended.�
�Layout� Considerations�
�1.� The� Input� capacitors,� Upper� FET,� Lower� FET,� Inductor�
�and� Output� capacitor� should� be� placed� first.� Isolate� these�
�power� components� on� the� topside� of� the� board� with� their�
�ground� terminals� adjacent� to� one� another.� Place� the� input�
�21�
�high� frequency� decoupling� ceramic� capacitor� very� close�
�to� the� MOSFETs.�
�2.� Use� separate� ground� planes� for� power� ground� and� small�
�signal� ground.� Connect� the� SGND� and� PGND� together�
�close� to� the� IC.� Do� not� connect� them� together� anywhere�
�else.�
�3.� The� loop� formed� by� Input� capacitor,� the� top� FET� and� the�
�bottom� FET� must� be� kept� as� small� as� possible.�
�4.� Ensure� the� current� paths� from� the� input� capacitor� to� the�
�MOSFET,� to� the� output� inductor� and� output� capacitor� are�
�as� short� as� possible� with� maximum� allowable� trace�
�widths.�
�5.� Place� The� PWM� controller� IC� close� to� lower� FET.� The�
�LGATE� connection� should� be� short� and� wide.� The� IC� can�
�be� best� placed� over� a� quiet� ground� area.� Avoid� switching�
�ground� loop� current� in� this� area.�
�6.� Place� VCC_5V� bypass� capacitor� very� close� to� VCC_5V�
�pin� of� the� IC� and� connect� its� ground� to� the� PGND� plane.�
�7.� Place� the� gate� drive� components� BOOT� diode� and� BOOT�
�capacitors� together� near� controller� IC.�
�8.� The� output� capacitors� should� be� placed� as� close� to� the�
�load� as� possible.� Use� short� wide� copper� regions� to�
�connect� output� capacitors-to-load� to� avoid� inductance�
�and� resistances.�
�9.� Use� copper� filled� polygons� or� wide� but� short� trace� to�
�connect� the� junction� of� upper� FET,� Lower� FET� and� output�
�inductor.� Also� keep� the� PHASE� node� connection� to� the� IC�
�short.� Do� not� unnecessarily� oversize� the� copper� islands�
�for� PHASE� node.� Since� the� phase� nodes� are� subjected� to�
�very� high� dv/dt� voltages,� the� stray� capacitor� formed�
�between� these� islands� and� the� surrounding� circuitry� will�
�tend� to� couple� switching� noise.�
�10.� Route� all� high� speed� switching� nodes� away� from� the�
�control� circuitry.�
�11.� Create� a� separate� small� analog� ground� plane� near� the� IC.�
�Connect� the� SGND� pin� to� this� plane.� All� small� signal�
�grounding� paths� including� feedback� resistors,� current�
�limit� setting� resistors� and� ENx� pull-down� resistors� should�
�be� connected� to� this� SGND� plane.�
�12.� Separate� current� sensing� traces� from� PHASE� node�
�connections�
�13.� Ensure� the� feedback� connection� to� the� output� capacitor� is�
�short� and� direct.�
�Component� Selection� Guidelines�
�MOSFET� Considerations�
�The� logic� level� MOSFETs� are� chosen� for� optimum� efficiency�
�given� the� potentially� wide� input� voltage� range� and� output�
�power� requirements.� Two� N-Channel� MOSFETs� are� used� in�
�each� of� the� synchronous-rectified� buck� converters� for� the� 3�
�PWM� outputs.� These� MOSFETs� should� be� selected� based�
�upon� r� DS(ON)� ,� gate� supply� requirements,� and� thermal�
�management� considerations.�
�FN6799.3�
�June� 24,� 2010�
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