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| 型号: | MAX1714AEEP+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 18/24页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM CM 20-QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| PWM 型: | 电流模式 |
| 输出数: | 1 |
| 频率 - 最大: | 600kHz |
| 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: | 20-SSOP(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
��
�
�High-Speed� Step-Down� Controller�
�for� Notebook� Computers�
�For� optimal� circuit� reliability,� choose� a� capacitor� that�
�has� less� than� 10°C� temperature� rise� at� the� peak� ripple�
�current.�
�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-cur-�
�fy� 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� breadboard� evaluation,� preferably� including�
�a� sanity� check� using� a� thermocouple� mounted� on� Q1.�
�?� V�
�rent� applications� usually� require� less� attention.�
�For� maximum� efficiency,� choose� a� high-side� MOSFET�
�(Q1)� that� has� conduction� losses� equal� to� the� switching�
�PD(Q1� switching)� =�
�2�
�C� RSS� IN(MAX)�
�I� GATE�
�?� f� ?� I� LOAD�
�losses� at� the� optimum� battery� voltage� (15V).� Check� to�
�ensure� that� the� conduction� losses� at� minimum� input�
�voltage� don� ’t� exceed� the� package� thermal� limits� or�
�violate� the� overall� thermal� budget.� Check� to� ensure� that�
�conduction� losses� plus� switching� losses� at� the� maxi-�
�mum� input� voltage� don’t� exceed� the� package� ratings� or�
�violate� the� overall� thermal� budget.�
�Choose� a� low-side� MOSFET� (Q2)� that� has� the� lowest�
�possible� R� DS(ON)� ,� comes� in� a� moderate� to� small� pack-�
�age� (i.e.,� SO-8),� and� is� reasonably� priced.� Ensure� that�
�the� MAX1714� DL� gate� driver� can� drive� Q2;� in� other�
�words,� check� that� the� gate� isn’t� pulled� up� by� the� high-�
�side� switch� turn� on,� due� to� parasitic� drain-to-gate� capac-�
�itance,� causing� cross-conduction� problems.� Switching�
�losses� aren’t� an� issue� for� the� low-side� MOSFET,� since� it’s�
�a� zero-voltage� switched� device� when� used� in� 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� due� to� resistance� occurs� at� minimum�
�battery� voltage:�
�PD(Q1� Resistive)� =� (V� OUT� /� V� IN(MIN)� )� ·� I� LOAD2� ·� R� DS(ON)�
�Generally,� a� small� high-side� MOSFET� is� desired� to�
�reduce� switching� losses� at� high� input� voltages.� However,�
�the� R� DS(ON)� required� to� stay� within� package� power-dissi-�
�pation� limits� often� limits� how� small� the� MOSFET� 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� approximately� 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� volt-�
�ages� becomes� extraordinarily� hot� when� subjected� to�
�V� IN(MAX)� ,� you� must� reconsider� your� choice� of� MOSFET.�
�Calculating� the� power� dissipation� in� Q1� due� to� switching�
�losses� is� difficult,� since� it� must� allow� for� difficult-to-quanti-�
�where� C� RSS� is� the� reverse� transfer� capacitance� of� Q1�
�and� I� GATE� is� the� peak� gate-drive� source/sink� current� (1A�
�typical).�
�For� the� low-side� MOSFET,� Q2,� the� worst-case� power� dis-�
�sipation� always� occurs� at� maximum� battery� voltage:�
�PD(Q2)� =� (1� -� V� OUT� /� V� IN(MAX)� )� ·� I� LOAD2� ·� R� DS(ON)�
�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,� you� must� “overdesign”� the� circuit�
�to� tolerate� I� LOAD� =� I� LIMIT(HIGH)� +� [(LIR� /� 2)� ·� I� LOAD(MAX)� ],�
�where� I� LIMIT(HIGH)� is� the� maximum� valley� current� allowed�
�by� the� current-limit� circuit,� including� threshold� tolerance�
�and� on-resistance� variation.� This� means� that� the�
�MOSFETs� must� be� very� well� heatsinked.� If� short-circuit�
�protection� without� overload� protection� is� enough,� a� nor-�
�mal� I� LOAD� value� can� be� used� for� calculating� component�
�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� if� efficien-�
�cy� isn’t� critical� it� can� be� removed.�
�Application� Issues�
�Dropout� Performance�
�The� output� voltage� adjust� range� for� continuous-conduc-�
�tion� operation� is� restricted� by� the� nonadjustable� 500ns�
�(max)� minimum� off-time� one-shot.� For� best� dropout� per-�
�formance,� 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-fac-�
�tor.� This� error� is� greater� at� higher� frequencies� (Table� 5).�
�Also,� keep� in� mind� that� transient� response� performance�
�of� buck� regulators� operated� close� to� dropout� is� poor,�
�18�
�______________________________________________________________________________________�
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相关代理商/技术参数 |
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| MAX1714AEEP-TG068 | 制造商:Rochester Electronics LLC 功能描述: 制造商:Maxim Integrated Products 功能描述: |
| MAX1714AEVKIT | 功能描述:电流型 PWM 控制器 Evaluation Kit for the MAX1714A RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MAX1714BEEE | 功能描述:电流型 PWM 控制器 RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MAX1714BEEE+ | 功能描述:电流型 PWM 控制器 Step-Down Controller for Notebook RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MAX1714BEEE+T | 功能描述:电流型 PWM 控制器 Step-Down Controller for Notebook RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
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