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参数资料
| 型号: | MAX8720EEI+ |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 16/31页 |
| 文件大小: | 0K |
| 描述: | IC CNTRL VID STP DWN 28-QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 50 |
| 应用: | 控制器,CPU GPU |
| 输入电压: | 2 V ~ 28 V |
| 输出数: | 1 |
| 输出电压: | 0.28 V ~ 1.85 V |
| 工作温度: | 0°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-QSOP |
| 供应商设备封装: | 28-QSOP |
| 包装: | 管件 |
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�Dynamically� Adjustable� 6-Bit� VID�
�Step-Down� Controller�
�threshold� between� pulse-skipping� PFM� and� nonskip-�
�ping� PWM� operation� to� coincide� with� the� boundary�
�between� continuous� and� discontinuous� inductor-cur-�
�rent� operation.� The� load-current� level� at� which�
�PFM/PWM� crossover� occurs,� I� LOAD(SKIP)� ,� is� equal� to�
�half� the� peak-to-peak� ripple� current,� which� is� a� function�
�of� the� inductor� value� (Figure� 3).� For� a� 7V� to� 24V� battery�
�range,� this� threshold� is� relatively� constant,� with� only� a�
�minor� dependence� on� battery� voltage:�
�sinking� current.� The� negative� current-limit� threshold�
�is� set� to� approximately� 120%� of� the� positive� current�
�limit,� and� therefore� tracks� the� positive� current� limit�
�when� ILIM� is� adjusted.�
�The� current-limit� threshold� is� adjusted� with� an� external�
�resistor-divider� at� ILIM.� The� current-limit� threshold� volt-�
�age� adjustment� range� is� from� 50mV� to� 200mV.� In� the�
�adjustable� mode,� the� current-limit� threshold� voltage� is�
�precisely� 1/10th� the� voltage� seen� at� ILIM.� The� threshold�
�I� LOAD� (� SKIP� )� =�
�KV� OUT� (V� IN� ?� V� OUT� )�
�2� LV� IN�
�defaults� to� 100mV� when� ILIM� is� connected� to� V� CC� .� The�
�logic� threshold� for� switchover� to� the� 100mV� default�
�value� is� approximately� V� CC� -� 1V.�
�where� K� is� the� on-time� scale� factor� (Table� 2).� For� exam-�
�ple,� in� the� standard� application� circuit� this� becomes:�
�Carefully� observe� the� PC� board� layout� guidelines� to�
�ensure� that� noise� and� DC� errors� do� not� corrupt� the� cur-�
�rent-sense� signals� seen� by� LX� and� PGND.� Place� the� IC�
�I� LOAD� (� SKIP� )� =�
�3.3� μ� s� ×� 1.25V(12V� ?� 1.25V)�
�2� ×� 0� .� 8� μ� H� ×� 12� V�
�=� 2� .� 31� A�
�close� to� the� low-side� MOSFET� with� short,� direct� traces,�
�making� a� Kelvin-sense� connection� to� the� source� and�
�drain� terminals.�
�The� crossover� point� occurs� at� a� lower� value� if� a� swing-�
�ing� (soft-saturation)� inductor� is� used.�
�The� switching� waveforms� may� appear� noisy� and� asyn-�
�chronous� when� light� loading� causes� pulse-skipping�
�operation,� but� this� is� a� normal� operating� condition� that�
�results� in� high� light-load� efficiency.� Trade-offs� in� PFM�
�noise� vs.� light-load� efficiency� are� made� by� varying� the�
�inductor� value.� Generally,� low� inductor� values� produce�
�a� broader� efficiency� vs.� load� curve,� while� higher� values�
�result� in� higher� full-load� efficiency� (assuming� that� the�
�coil� resistance� remains� fixed)� and� less� output� voltage�
�ripple.� Penalties� for� using� higher� inductor� values�
�include� larger� physical� size� and� degraded� load-tran-�
�sient� response,� especially� at� low� input-voltage� levels.�
�Current-Limit� Circuit�
�The� current-limit� circuit� employs� a� unique� “valley”� cur-�
�rent-sensing� algorithm� that� uses� the� on-resistance� of�
�the� low-side� MOSFET� as� a� current-sensing� element.� If�
�the� current-sense� signal� is� above� the� current-limit�
�threshold,� the� PWM� is� not� allowed� to� initiate� a� new�
�cycle� (Figure� 4).� The� actual� peak� current� is� greater� than�
�the� current-limit� threshold� by� an� amount� equal� to� the�
�inductor� ripple� current.� Therefore,� the� exact� current-�
�limit� characteristic� and� maximum� load� capability� are� a�
�function� of� the� MOSFET� on-resistance,� inductor� value,�
�and� battery� voltage.� The� reward� for� this� uncertainty� is�
�robust,� lossless� overcurrent� sensing.� When� combined�
�with� the� undervoltage-protection� circuit,� this� current-�
�limit� method� is� effective� in� almost� every� circumstance.�
�There� is� also� a� negative� current� limit� that� prevents�
�excessive� reverse� inductor� currents� when� V� OUT� is�
�MOSFET� Gate� Drivers� (DH,� DL)�
�The� DH� and� DL� drivers� are� optimized� for� driving� moder-�
�ate-sized� high-side� and� larger� low-side� power� MOSFETs.�
�This� is� consistent� with� the� low� duty� factor� seen� in� the�
�notebook� CPU� environment,� where� a� large� V� IN� -� V� OUT�
�differential� exists.� An� adaptive� dead-time� circuit� monitors�
�the� DL� output� and� prevents� the� high-side� FET� from� turn-�
�ing� on� until� DL� is� fully� off.� There� must� be� a� low-resis-�
�tance,� low-inductance� path� from� the� DL� driver� to� the�
�MOSFET� gate� for� the� adaptive� dead-time� circuit� to� work�
�properly.� Otherwise,� the� sense� circuitry� in� the� MAX8720�
�interprets� the� MOSFET� gate� as� “off”� while� there� is� actual-�
�ly� still� charge� left� on� the� gate.� Use� very� short,� wide� traces�
�measuring� 10� to� 20� squares� (50� to� 100� mils� wide� if� the�
�MOSFET� is� 1in� from� the� MAX8720).�
�The� dead� time� at� the� other� edge� (DH� turning� off)� is�
�determined� by� a� fixed� 35ns� (typ)� internal� delay.�
�The� internal� pulldown� transistor� that� drives� DL� low� is�
�robust,� with� a� 0.4� ?� (typ)� on-resistance.� This� helps� pre-�
�vent� DL� from� being� pulled� up� during� the� fast� rise� time� of�
�the� inductor� node,� due� to� capacitive� coupling� from� the�
�drain� to� the� gate� of� the� low-side� synchronous-rectifier�
�MOSFET.� Applications� with� high� input� voltages� and�
�long,� inductive� DL� traces� may� require� additional� gate-to-�
�source� capacitance� to� ensure� fast-rising� LX� edges� do�
�not� pull� up� the� low-side� MOSFET’s� gate� voltage,� caus-�
�ing� shoot-through� currents.� The� capacitive� coupling�
�between� LX� and� DL� created� by� the� MOSFET’s� gate-to-�
�drain� capacitance� (C� RSS� ),� gate-to-source� capacitance�
�(C� ISS� -� C� RSS� ),� and� additional� board� parasitics� should�
�not� exceed� the� minimum� threshold� voltage:�
�16�
�______________________________________________________________________________________�
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相关代理商/技术参数 |
参数描述 |
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| MAX8720EEI+ | 功能描述:DC/DC 开关控制器 Dyn Adj 6-Bit VID 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 |
| MAX8720EEI+T | 功能描述:DC/DC 开关控制器 Dyn Adj 6-Bit VID 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 |
| MAX8720EEI-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 |
| MAX8720ETX | 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 |
| MAX8720ETX+ | 功能描述:DC/DC 开关控制器 Dyn Adj 6-Bit VID 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 |
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