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参数资料
| 型号: | ISL8112EVAL1Z |
| 厂商: | Intersil |
| 文件页数: | 24/27页 |
| 文件大小: | 0K |
| 描述: | EVALUATION BOARD FOR ISL8112 |
| 标准包装: | 1 |
| 主要目的: | DC/DC,步降 |
| 输出及类型: | 2,非隔离 |
| 输出电压: | 0.7 ~ 5.5 V |
| 电流 - 输出: | 200mA |
| 输入电压: | 5.5 ~ 25 V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 可调式 |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | ISL8112 |
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�ISL8112�
�?� V� OUT� (� V� IN� –� V� OUT_� )� ?�
�I� RMS� ≈� I� LOAD� ?� ------------------------------------------------------------� ?�
�PD� (� Q� H� Switching� )� =� (� V� IN� (� MAX� )� )� ?� ?�
�2� ?� C� RSS� ?� f� SW� ?� I� LOAD� ?�
�I� GATE�
�(EQ.� 17)�
�?� V� IN� ?�
�When� V� IN� =� 2� ?� V� OUT_� (� D� =� 50%� )� ,� IRMS� has� maximum�
�current� of� I� LOAD� ?� 2� .�
�The� ESR� of� the� input-capacitor� is� important� for� determining�
�capacitor� power� dissipation.� All� the� power� (I� RMS2� x� ESR)�
�heats� up� the� capacitor� and� reduces� efficiency.� Nontantalum�
�chemistries� (ceramic� or� OS-CON)� are� preferred� due� to� their�
�low� ESR� and� resilience� to� power-up� surge� currents.� Choose�
�input� capacitors� that� exhibit� less� than� +10°C� temperature�
�rise� at� the� RMS� input� current� for� optimal� circuit� longevity.�
�Place� the� drains� of� the� high-side� switches� close� to� each�
�other� to� share� common� input� bypass� capacitors.�
�Power� MOSFET� Selection�
�Most� of� the� following� MOSFET� guidelines� focus� on� the�
�challenge� of� obtaining� high� load-current� capability� (>5A)�
�when� using� high-voltage� (>20V)� AC� adapters.� Low-current�
�applications� usually� require� less� attention.�
�Choose� a� high-side� MOSFET� (Q1/Q3)� that� has� conduction�
�adequate� r� DS(ON)� at� low� battery� voltages� if� it� becomes�
�extraordinarily� hot� when� subjected� to� V� IN(MAX)� .�
�Calculating� the� power� dissipation� in� NH� (Q1/Q3)� due� to�
�switching� losses� is� difficult� since� it� must� allow� for� quantifying�
�factors� that� influence� the� turn-on� and� turn-off� times.� These�
�factors� include� the� internal� gate� resistance,� gate� charge,�
�threshold� voltage,� source� inductance,� and� PC� board� layout�
�characteristics.� The� following� switching-loss� calculation�
�provides� only� a� very� rough� estimate� and� is� no� substitute� for�
�bench� evaluation,� preferably� including� verification� using� a�
�thermocouple� mounted� on� NH� (Q1/Q3):�
�-----------------------------------------------------�
�?� ?�
�(EQ.� 19)�
�where� C� RSS� is� the� reverse� transfer� capacitance� of� Q� H�
�(Q1/Q3)� and� I� GATE� is� the� peak� gate-drive� source/sink�
�current.�
�For� the� synchronous� rectifier,� the� worst-case� power�
�dissipation� always� occurs� at� maximum� battery� voltage:�
�PD� (� Q� L� )� =� ?� 1� –� --------------------------� ?� I� LOAD� ?� r� DS� (� ON� )�
�losses� equal� to� the� switching� losses� at� the� typical� battery�
�voltage� for� maximum� efficiency.� Ensure� that� the� conduction�
�losses� at� the� minimum� input� voltage� do� not� exceed� the�
�?� V� OUT� ?� 2�
�?� V� IN� (� MAX� )� ?�
�(EQ.� 20)�
�package� thermal� limits� or� violate� the� overall� thermal� budget.�
�Ensure� that� conduction� losses� plus� switching� losses� at� the�
�maximum� input� voltage� do� not� exceed� the� package� ratings�
�or� violate� the� overall� thermal� budget.�
�Choose� a� synchronous� rectifier� (Q2/Q4)� with� the� lowest�
�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:�
�possible� r� DS(ON)� .� Ensure� the� gate� is� not� pulled� up� by� the�
�high-side� switch� turning� on� due� to� parasitic� drain-to-gate�
�I� LOAD� =� I� LIMIT� (� HIGH� )� +� (� (� LIR� )� ?� 2� )� ?� I� LOAD� (� MAX� )�
�(EQ.� 21)�
�capacitance,� causing� cross-conduction� problems.� Switching�
�losses� are� not� an� issue� for� the� synchronous� rectifier� in� the�
�buck� topology� since� it� is� a� zero-voltage� switched� device�
�when� using� the� buck� topology.�
�MOSFET� Power� Dissipation�
�Worst-case� conduction� losses� occur� at� the� duty-factor�
�extremes.� For� the� high-side� MOSFET,� the� worst-case� power�
�dissipation� (PD)� due� to� the� MOSFET's� r� DS(ON)� occurs� at� the�
�minimum� battery� voltage:�
�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�
�PD� (� Q� H� Resistance� )� =� ?� ------------------------� ?� (� I� LOAD� )� ?� r� DS� (� ON� )�
�I� L� ?� r� DS� (� ON� )�
�?� V� OUT_� ?� 2�
�?� V� IN� (� MIN� )� ?�
�(EQ.� 18)�
�while� both� switches� are� off� (dead� time).� The� drop� is�
�when� the� low-side� switch� conducts.�
�Generally,� a� small� high-side� MOSFET� reduces� switching�
�losses� at� high� input� voltage.� However,� the� r� DS(ON)� required�
�to� stay� within� package� power-dissipation� limits� often� limits�
�how� small� the� MOSFET� can� be.� The� optimum� situation�
�occurs� when� the� switching� (AC)� losses� equal� the� conduction�
�(� rDS(ON)� )� losses.�
�Switching� losses� in� the� high-side� MOSFET� can� become� an�
�insidious� heat� problem� when� maximum� battery� voltage� is�
�applied,� due� to� the� squared� term� in� the� CV� 2� f� switching-loss�
�equation.� Reconsider� the� high-side� MOSFET� chosen� for�
�24�
�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�
�FN6396.1�
�August� 10,� 2010�
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