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参数资料
| 型号: | ISL6236EVAL2 |
| 厂商: | Intersil |
| 文件页数: | 33/35页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD 2 FOR ISL6236 |
| 标准包装: | 1 |
| 系列: | * |
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�ISL6236�
�I� LOAD� =� I� LIMIT� (� HIGH� )� +� (� (� LIR� )� ?� 2� )� ?� I� LOAD� (� MAX� )�
�(� V� OUT_� +� V� DROP� )�
�V� IN� (� MIN� )� =� ---------------------------------------------------� +� V� DROP2� –� V� DROP1�
�t� OFF� (� MIN� )� ?� h�
�1� –� ?� ------------------------------------� ?�
�(� 5V� +� 0.1V� )�
�V� IN� (� MIN� )� =� ----------------------------------------------� +� 0.1V� –� 0.1V� =� 6.65V�
�1� –� ?� -------------------------------� ?�
�The� absolute� worst� case� for� MOSFET� power� dissipation�
�occurs� under� heavy� overloads� that� are� greater� than�
�I� LOAD(MAX)� but� are� not� quite� high� enough� to� exceed� the�
�current� limit� and� cause� the� fault� latch� to� trip.� To� protect�
�against� this� possibility,� "overdesign"� the� circuit� to� tolerate:�
�(EQ.� 22)�
�where� I� LIMIT(HIGH)� is� the� maximum� valley� current� allowed�
�by� the� current-limit� circuit,� including� threshold� tolerance� and�
�resistance� variation.�
�Rectifier� Selection�
�Current� circulates� from� ground� to� the� junction� of� both�
�MOSFETs� and� the� inductor� when� the� high-side� switch� is� off.�
�As� a� consequence,� the� polarity� of� the� switching� node� is�
�negative� with� respect� to� ground.� This� voltage� is� approximately�
�-0.7V� (a� diode� drop)� at� both� transition� edges� while� both�
�switches� are� off� (dead� time).� The� drop� is� I� L� x� r� DS(ON)� when�
�the� low-side� switch� conducts.�
�The� rectifier� is� a� clamp� across� the� synchronous� rectifier� that�
�catches� the� negative� inductor� swing� during� the� dead� time�
�between� turning� the� high-side� MOSFET� off� and� the�
�synchronous� rectifier� on.� The� MOSFETs� incorporate� a�
�high-speed� silicon� body� diode� as� an� adequate� clamp� diode� if�
�efficiency� is� not� of� primary� importance.� Place� a� Schottky�
�diode� in� parallel� with� the� body� diode� to� reduce� the� forward�
�voltage� drop� and� prevent� the� Q2/Q4� MOSFET� body� diodes�
�from� turning� on� during� the� dead� time.� Typically,� the� external�
�diode� improves� the� efficiency� by� 1%� to� 2%.� Use� a� Schottky�
�diode� with� a� DC� current� rating� equal� to� one-third� of� the� load�
�current.� For� example,� use� an� MBR0530� (500mA-rated)� type�
�for� loads� up� to� 1.5A,� a� 1N5817� type� for� loads� up� to� 3A,� or� a�
�1N5821� type� for� loads� up� to� 10A.� The� rectifier's� rated�
�reverse� breakdown� voltage� must� be� at� least� equal� to� the�
�maximum� input� voltage,� preferably� with� a� 20%� derating�
�factor.�
�Applications� Information�
�(� Δ� I� UP� ).� The� ratio� h� =� Δ� I� UP� /� Δ� I� DOWN� indicates� the� ability� to�
�slew� the� inductor� current� higher� in� response� to� increased�
�load,� and� must� always� be� greater� than� 1.� As� h� approaches� 1,�
�the� absolute� minimum� dropout� point,� the� inductor� current� is�
�less� able� to� increase� during� each� switching� cycle� and� V� SAG�
�greatly� increases� unless� additional� output� capacitance� is�
�used.�
�A� reasonable� minimum� value� for� h� is� 1.5,� but� this� can� be�
�adjusted� up� or� down� to� allow� trade-offs� between� V� SAG,�
�output� capacitance� and� minimum� operating� voltage.� For� a�
�given� value� of� h,� the� minimum� operating� voltage� can� be�
�calculated� as:�
�(EQ.� 23)�
�?� K� ?�
�where� V� DROP1� and� V� DROP2� are� the� parasitic� voltage� drops� in�
���Specifications”� table,� which� starts� on� page� 3� and� K� is� taken�
�from� Table� 2.� The� absolute� minimum� input� voltage� is�
�calculated� with� h� =� 1.�
�Operating� frequency� must� be� reduced� or� h� must� be�
�increased� and� output� capacitance� added� to� obtain� an�
�acceptable� V� SAG� if� calculated� V� IN(MIN)� is� greater� than� the�
�required� minimum� input� voltage.� Calculate� V� SAG� to� be� sure�
�of� adequate� transient� response� if� operation� near� dropout� is�
�anticipated.�
�DROPOUT� DESIGN� EXAMPLE�
�ISL6236:� With� V� OUT2� =� 5V,� f� SW� =� 400kHz,� K� =� 2.25μs,�
�t� OFF(MIN)� =� 350ns,� V� DROP1� =� V� DROP2� =� 100mV,� and�
�h� =� 1.5,� the� minimum� V� IN� is:�
�(EQ.� 24)�
�0.35� μ� s� ?� 1.5�
�?� 2.25� μ� s� ?�
�Calculating� with� h� =� 1� yields:�
�V� IN� (� MIN� )� =� -----------------------------------------� +� 0.1V� –� 0.1V� =� 6.04V�
�1� –� ?� --------------------------� ?�
�Dropout� Performance�
�The� output� voltage-adjust� range� for� continuous-conduction�
�operation� is� restricted� by� the� nonadjustable� 350ns� (max)�
�minimum� OFF-time� one-shot.� Use� the� slower� 5V� SMPS� for�
�(� 5V� +� 0.1V� )�
�0.35� μ� s� ?� 1�
�?� 2.25� μ� s� ?�
�(EQ.� 25)�
�the� higher� of� the� two� output� voltages� for� best� dropout�
�performance� in� adjustable� feedback� mode.� The� duty-factor�
�limit� must� be� calculated� using� worst-case� values� for� on� -� and�
�OFF-times,� when� working� with� low� input� voltages.�
�Manufacturing� tolerances� and� internal� propagation� delays�
�introduce� an� error� to� the� t� ON� K-factor.� Also,� keep� in� mind� that�
�transient-response� performance� of� buck� regulators� operated�
�close� to� dropout� is� poor,� and� bulk� output� capacitance� must�
�often� be� added� (see� Equation� 11� on� page� 31).�
�The� absolute� point� of� dropout� occurs� when� the� inductor�
�current� ramps� down� during� the� minimum� OFF-time�
�(� Δ� I� DOWN� )� as� much� as� it� ramps� up� during� the� ON-time�
�33�
�Therefore,� V� IN� must� be� greater� than� 6.65V.� A� practical� input�
�voltage� with� reasonable� output� capacitance� would� be� 7.5V.�
�PC� Board� Layout� Guidelines�
�Careful� PC� board� layout� is� critical� to� achieve� minimal� switching�
�losses� and� clean,� stable� operation.� This� is� especially� true� when�
�multiple� converters� are� on� the� same� PC� board� where� one�
�circuit� can� affect� the� other.� Refer� to� the� ISL6236� Evaluation� Kit�
�Application� Notes� (AN1271� and� AN1272)� for� a� specific� layout�
�example.�
�FN6373.6�
�April� 29,� 2010�
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