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| 型号: | MAX1715EEI |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 20/25页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 28-QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 50 |
| PWM 型: | 控制器 |
| 输出数: | 2 |
| 频率 - 最大: | 620kHz |
| 占空比: | 100% |
| 电源电压: | 4.5 V ~ 5.5 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 28-SSOP(0.154",3.90mm 宽) |
| 包装: | 管件 |
��
�
�Ultra-High� Efficiency,� Dual� Step-Down�
�Controller� for� Notebook� Computers�
�power� dissipation� (PD)� due� to� resistance� occurs� at�
�minimum� battery� voltage:�
�where� I� LIMIT(HIGH)� is� the� maximum� valley� current�
�allowed� by� the� current-limit� circuit,� including� threshold�
�?� V� IN� (� MIN� )� ?� LOAD�
�� R� DS� (� )�
�?� V� OUT� ?�
�PD(Q1� resistance)� =� ?� ?� I�
�?� ?�
�2�
�ON�
�tolerance� and� on-resistance� variation.� This� means� that�
�the� MOSFETs� must� be� very� well� heatsinked.� If� short-cir-�
�cuit� protection� without� overload� protection� is� enough,� a�
�normal� I� LOAD� value� can� be� used� for� calculating� com-�
�C� RSS� � V� IN(MAX)2� � f� � I� LOAD�
�DUTY� =�
�=�
�=� 80.6%�
�� R� DS� (� ON� )�
�?� V� IN� (� MAX� )� ?� LOAD�
�Generally, a small high-side MOSFET is desired in�
�order� to� reduce� switching� losses� at� high� input� voltages.�
�However,� the� R� DS(ON)� required� to� stay� within� package�
�power-dissipation� limits� often� limits� how� small� the� MOS-�
�FET� can� be.� Again,� the� optimum� occurs� when� the�
�switching� (AC)� losses� equal� the� conduction� (R� DS(ON)� )�
�losses.� High-side� switching� losses� don� ’t� usually�
�become� an� issue� until� the� input� is� greater� than� approxi-�
�mately� 15V.�
�Switching� losses� in� the� high-side� MOSFET� can� become�
�an� insidious� heat� problem� when� maximum� AC� adapter�
�voltages� are� applied,� due� to� the� squared� term� in� the�
�CV� 2� F� switching� loss� equation.� If� the� high-side� MOSFET�
�you’ve� chosen� for� adequate� R� DS(ON)� at� low� battery�
�voltages� becomes� extraordinarily� hot� when� subjected�
�to� V� IN(MAX)� ,� reconsider� your� choice� of� MOSFET.�
�Calculating� the� power� dissipation� in� Q1� due� to� switch-�
�ing� losses� is� difficult� since� it� must� allow� for� difficult�
�quantifying� factors� that� influence� the� turn-on� and� turn-�
�off� times.� These� factors� include� the� internal� gate� resis-�
�tance,� 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� bread-�
�board� evaluation,� preferably� including� a� verification�
�using� a� thermocouple� mounted� on� Q1:�
�PD(Q1� switching)� =�
�I� GATE�
�where� C� RSS� is� the� reverse� transfer� capacitance� of� Q1�
�and� I� GATE� is� the� peak� gate-drive� source/sink� current�
�(1A� typ).�
�For� the� low-side� MOSFET,� Q2,� the� worst-case� power�
�dissipation� always� occurs� at� maximum� battery� voltage:�
�?� 1� -� V� OUT� ?� 2�
�PD(Q2)� =� ?� ?� I�
�?� ?�
�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� pro-�
�tect� against� this� possibility,� you� must� “overdesign”� the�
�circuit� to� tolerate:�
�I� LOAD� =� I� LIMIT(HIGH)� +� (LIR� /� 2)� ?� I� LOAD(MAX)�
�ponent� stresses.�
�Choose� a� Schottky� diode� (D1)� having� a� forward� voltage�
�low� enough� to� prevent� the� Q2� MOSFET� body� diode�
�from� turning� on� during� the� dead� time.� As� a� general�
�rule,� a� diode� having� a� DC� current� rating� equal� to� 1/3� of�
�the� load� current� is� sufficient.� This� diode� is� optional� and�
�can� be� removed� if� efficiency� isn’t� critical.�
�_________________Application� Issues�
�Dropout� Performance�
�The� output� voltage� adjust� range� for� continuous-con-�
�duction� operation� is� restricted� by� the� nonadjustable�
�500ns� (max)� minimum� off-time� one-shot.� For� best�
�dropout� performance,� use� the� slowest� (200kHz)� on-�
�time� setting.� When� working� with� low� input� voltages,� the�
�duty-factor� limit� must� be� calculated� using� worst-case�
�values� for� on-� and� off-times.� Manufacturing� tolerances�
�and� internal� propagation� delays� introduce� an� error� to�
�the� TON� K-factor.� This� error� is� greater� at� higher� fre-�
�quencies� (Table� 5).� 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� the� VSAG� equation� in� the�
�Design� Procedure� ).�
�Dropout� design� example:� V� IN� =� 3V� min,� V� OUT� =� 2V,� f�
�=� 300kHz.� The� required� duty� is� (V� OUT� +� V� SW� )� /� (V� IN� -�
�V� SW� )� =� (2V� +� 0.1V)� /� (3.0V� -� 0.1V)� =� 72.4%.� The� worst-�
�case� on-time� is� (V� OUT� +� 0.075)� /� V� IN� ?� K� =� 2.075V� /� 3V�
�?� 3.35μs-V� ?� 90%� =� 2.08μs.� The� IC� duty-factor� limitation�
�is:�
�t� ON(MIN)� 2.08� μ� s�
�t� ON(MIN)� +� t� OFF(MAX)� 2.08� μ� s� +� 500ns�
�which� meets� the� required� duty.�
�Remember� to� include� inductor� resistance� and� MOSFET�
�on-state� voltage� drops� (V� SW� )� when� doing� worst-case�
�dropout� duty-factor� calculations.�
�All-Ceramic-Capacitor� Application�
�Ceramic� capacitors� have� advantages� and� disadvan-�
�tages.� They� have� ultra-low� ESR� and� are� noncom-�
�bustible,� relatively� small,� and� nonpolarized.� They� are�
�also� expensive� and� brittle,� and� their� ultra-low� ESR� char-�
�acteristic� can� result� in� excessively� high� ESR� zero� fre-�
�quencies� (affecting� stability).� In� addition,� their� relatively�
�low� capacitance� value� can� cause� output� overshoot�
�20�
�______________________________________________________________________________________�
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相关代理商/技术参数 |
参数描述 |
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| MAX1715EEI+ | 功能描述:DC/DC 开关控制器 Dual Step-Down Controller RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| MAX1715EEI+T | 功能描述:DC/DC 开关控制器 Dual Step-Down Controller RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| MAX1715EEI-T | 功能描述:DC/DC 开关控制器 RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| MAX1715EVKIT | 功能描述:DC/DC 开关控制器 Evaluation Kit for the MAX1715 RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| MAX1716EEG | 功能描述:DC/DC 开关控制器 RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
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