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参数资料
| 型号: | ISL8104EVAL2Z |
| 厂商: | Intersil |
| 文件页数: | 11/14页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD 2 FOR ISL8104 |
| 标准包装: | 1 |
| 系列: | * |
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�ISL8104�
�transient� loading.� Unfortunately,� ESL� is� not� a� specified�
�parameter.� Work� with� your� capacitor� supplier� and� measure�
�the� capacitor� ’s� impedance� with� frequency� to� select� a�
�suitable� component.� In� most� cases,� multiple� electrolytic�
�capacitors� of� small� case� size� perform� better� than� a� single�
�large� case� capacitor.�
�Output� Inductor� Selection�
�The� output� inductor� is� selected� to� meet� the� output� voltage�
�ripple� requirements� and� minimize� the� converter� ’s� response�
�time� to� the� load� transient.� The� inductor� value� determines� the�
�converter� ’s� ripple� current� and� the� ripple� voltage� is� a� function�
�of� the� ripple� current.� The� ripple� voltage� and� current� are�
�approximated� by� Equation� 15:�
�The� important� parameters� for� the� bulk� input� capacitor� are� the�
�voltage� rating� and� the� RMS� current� rating.� For� reliable�
�operation,� select� a� bulk� capacitor� with� voltage� and� current�
�ratings� above� the� maximum� input� voltage� and� largest� RMS�
�current� required� by� the� circuit.� The� capacitor� voltage� rating�
�should� be� at� least� 1.25� times� greater� than� the� maximum�
�input� voltage,� a� voltage� rating� of� 1.5� times� greater� is� a�
�conservative� guideline.� The� RMS� current� rating� requirement�
�for� the� input� capacitor� of� a� buck� regulator� is� approximately�
�1/2� the� DC� load� current.�
�For� a� through� hole� design,� several� electrolytic� capacitors�
�(Panasonic� HFQ� series� or� Nichicon� PL� series� or� Sanyo� MV-GX�
�or� equivalent)� may� be� needed.� For� surface� mount� designs,�
�V� IN� -� V� OUT� V� OUT�
�V� IN�
�Δ� I� =� --------------------------------� ?� ----------------�
�Fs� x� L�
�Δ� V� OUT� =� Δ� I� x� ESR�
�(EQ.� 15)�
�solid� tantalum� capacitors� can� be� used,� but� caution� must� be�
�exercised� with� regard� to� the� capacitor� surge� current� rating.�
�These� capacitors� must� be� capable� of� handling� the� surge-�
�Increasing� the� value� of� inductance� reduces� the� ripple� current�
�and� voltage.� However,� the� large� inductance� values� reduce�
�the� converter� ’s� response� time� to� a� load� transient.�
�One� of� the� parameters� limiting� the� converter’s� response� to� a�
�load� transient� is� the� time� required� to� change� the� inductor�
�current.� Given� a� sufficiently� fast� control� loop� design,� the�
�ISL8104� will� provide� either� 0%� or� 100%� duty� cycle� in�
�response� to� a� load� transient.� The� response� time� is� the� time�
�required� to� slew� the� inductor� current� from� an� initial� current�
�value� to� the� transient� current� level.� During� this� interval� the�
�difference� between� the� inductor� current� and� the� transient�
�current� level� must� be� supplied� by� the� output� capacitor.�
�Minimizing� the� response� time� can� minimize� the� output�
�capacitance� required.�
�The� response� time� to� a� transient� load� is� different� for� the�
�application� of� load� and� the� removal� of� load.� Equation� 16�
�gives� the� approximate� response� time� interval� for� application�
�current� at� power-up.� The� TPS� series� available� from� AVX,� and�
�the� 593D� series� from� Sprague� are� both� surge� current� tested.�
�MOSFET� Selection/Considerations�
�The� ISL8104� requires� at� least� 2� N-Channel� power� MOSFETs.�
�These� should� be� selected� based� upon� r� DS(ON)� ,� gate� supply�
�requirements,� and� thermal� management� requirements.�
�In� high-current� applications,� the� MOSFET� power� dissipation,�
�package� selection� and� heatsink� are� the� dominant� design�
�factors.� The� power� dissipation� includes� two� loss�
�components;� conduction� loss� and� switching� loss.� At� a�
�300kHz� switching� frequency,� the� conduction� losses� are� the�
�largest� component� of� power� dissipation� for� both� the� top-side�
�and� the� bottom-side� MOSFETs.� These� losses� are� distributed�
�between� the� two� MOSFETs� according� to� duty� factor� (see� the�
�following� equations).� Only� the� top-side� MOSFET� exhibits�
�switching� losses,� since� the� schottky� rectifier� clamps� the�
�switching� node� before� the� synchronous� rectifier� turns� on.�
�t� RISE� =� --------------------------------� t� FALL� =� -------------------------------�
�P� top-side� =� I� O2� x� r� DS(ON)� x� D� +� 1� Io� x� V� IN� x� t� SW� x� f� SW�
�and� removal� of� a� transient� load:�
�L� O� � I� TRAN� L� O� � I� TRAN�
�V� IN� –� V� OUT� V� OUT�
�(EQ.� 16)�
�2�
�P� bottom-side� =� I� O2� x� r� DS(ON)� x� (1� -� D)�
�where:� I� TRAN� is� the� transient� load� current� step,� t� RISE� is� the�
�response� time� to� the� application� of� load,� and� t� FALL� is� the�
�response� time� to� the� removal� of� load.� With� a� +5V� input�
�source,� the� worst� case� response� time� can� be� either� at� the�
�where:� D� is� the� duty� cycle� =� V� O� /� V� IN� ,�
�t� SW� is� the� switching� interval,� and�
�f� SW� is� the� switching� frequency.�
�(EQ.� 17)�
�application� or� removal� of� load� and� dependent� upon� the�
�output� voltage� setting.� Be� sure� to� check� both� of� these�
�equations� at� the� minimum� and� maximum� output� levels� for�
�the� worst� case� response� time.�
�Input� Capacitor� Selection�
�Use� a� mix� of� input� bypass� capacitors� to� control� the� voltage�
�overshoot� across� the� MOSFETs.� Use� small� ceramic�
�capacitors� for� high� frequency� decoupling� and� bulk� capacitors�
�to� supply� the� current� needed� each� time� Q1� turns� on.� Place� the�
�small� ceramic� capacitors� physically� close� to� the� MOSFETs�
�and� between� the� drain� of� Q� 1� and� the� source� of� Q� 2� .�
�11�
�Equation� 17� assumes� linear� voltage-current� transitions� and�
�does� not� adequately� model� power� loss� due� to� the�
�reverse-recovery� of� the� bottom-side� MOSFETs� body� diode.�
�The� gate-charge� losses� are� dissipated� by� the� ISL8104� and�
�don't� heat� the� MOSFETs.� However,� large� gate-charge�
�increases� the� switching� interval,� t� SW� which� increases� the�
�top-side� 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.�
�A� separate� heatsink� may� be� necessary� depending� upon�
�MOSFET� power,� package� type,� ambient� temperature� and� air�
�flow.�
�FN9257.2�
�March� 7,� 2008�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| ISL8104IBZ | 功能描述:IC REG CTRLR BUCK PWM VM 14-SOIC RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 产品培训模块:Lead (SnPb) Finish for COTS Obsolescence Mitigation Program 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:275kHz 占空比:50% 电源电压:18 V ~ 110 V 降压:无 升压:无 回扫:无 反相:无 倍增器:无 除法器:无 Cuk:无 隔离:是 工作温度:-40°C ~ 85°C 封装/外壳:8-SOIC(0.154",3.90mm 宽) 包装:带卷 (TR) |
| ISL8104IBZ | 制造商:Intersil Corporation 功能描述:Pulse Width Modulation (PWM) Controller |
| ISL8104IBZ-T | 功能描述:IC REG CTRLR BUCK PWM VM 14-SOIC RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 产品培训模块:Lead (SnPb) Finish for COTS Obsolescence Mitigation Program 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:275kHz 占空比:50% 电源电压:18 V ~ 110 V 降压:无 升压:无 回扫:无 反相:无 倍增器:无 除法器:无 Cuk:无 隔离:是 工作温度:-40°C ~ 85°C 封装/外壳:8-SOIC(0.154",3.90mm 宽) 包装:带卷 (TR) |
| ISL8104IRZ | 功能描述:IC REG CTRLR BUCK PWM VM 16-QFN RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 产品培训模块:Lead (SnPb) Finish for COTS Obsolescence Mitigation Program 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:275kHz 占空比:50% 电源电压:18 V ~ 110 V 降压:无 升压:无 回扫:无 反相:无 倍增器:无 除法器:无 Cuk:无 隔离:是 工作温度:-40°C ~ 85°C 封装/外壳:8-SOIC(0.154",3.90mm 宽) 包装:带卷 (TR) |
| ISL8104IRZ-T | 功能描述:IC REG CTRLR BUCK PWM VM 16-QFN RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 产品培训模块:Lead (SnPb) Finish for COTS Obsolescence Mitigation Program 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:275kHz 占空比:50% 电源电压:18 V ~ 110 V 降压:无 升压:无 回扫:无 反相:无 倍增器:无 除法器:无 Cuk:无 隔离:是 工作温度:-40°C ~ 85°C 封装/外壳:8-SOIC(0.154",3.90mm 宽) 包装:带卷 (TR) |
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