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| 型号: | MAX17004ETJ+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 25/36页 |
| 文件大小: | 0K |
| 描述: | IC PS CTRLR FOR NOTEBOOKS 32TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 应用: | 控制器,笔记本电脑电源系统 |
| 输入电压: | 6 V ~ 26 V |
| 输出数: | 4 |
| 输出电压: | 3.3V,5V,2 V ~ 5.5 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-WFQFN 裸露焊盘 |
| 供应商设备封装: | 32-TQFN-EP(5x5) |
| 包装: | 带卷 (TR) |
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�High-Efficiency,� Quad-Output,� Main� Power-�
�Supply� Controllers� for� Notebook� Computers�
�Auxiliary� LDO� Detailed� Description�
�The� MAX17003/MAX17004� include� an� auxiliary� linear�
�regulator� (OUTA)� that� can� be� configured� for� 12V,� ideal� for�
�PCMCIA� power� requirements,� and� for� biasing� the� gates�
�of� load� switches� in� a� portable� device.� OUTA� can� also� be�
�configured� for� outputs� from� 1V� to� 23V.� The� auxiliary� regu-�
�lator� has� an� independent� ON/OFF� control,� allowing� it� to�
�be� shut� down� when� not� needed,� reducing� power� con-�
�sumption� when� the� system� is� in� a� low-power� state.�
�?�
�?�
�Switching� Frequency.� This� choice� determines� the�
�basic� trade-off� between� size� and� efficiency.� The� opti-�
�mal� frequency� is� largely� a� function� of� maximum� input�
�voltage,� due� to� MOSFET� switching� losses� that� are�
�proportional� to� frequency� and� V� IN� 2� .� The� optimum� fre-�
�quency� is� also� a� moving� target,� due� to� rapid� improve-�
�ments� in� MOSFET� technology� that� are� making� higher�
�frequencies� more� practical.�
�Inductor� Operating� Point.� This� choice� provides�
�V� OUT� (� V� IN� ?� V� OUT� )�
�A flyback-winding control loop regulates a secondary�
�winding� output,� improving� cross-regulation� when� the� pri-�
�mary� output� is� lightly� loaded� or� when� there� is� a� low� input-�
�output� differential� voltage.� If� V� DRVA� <� V� OUTA� ,� the�
�low-side� switch� is� turned� on� for� a� time� equal� to� 33%� of�
�the� switching� period.� This� reverses� the� inductor� (primary)�
�current,� pulling� current� from� the� output� filter� capacitor�
�and� causing� the� flyback� transformer� to� operate� in� for-�
�ward� mode.� The� low� impedance� presented� by� the� trans-�
�former� secondary� in� forward� mode� dumps� current� into�
�the� secondary� output,� charging� up� the� secondary�
�capacitor� and� bringing� V� INA� -� V� OUTA� back� into� regula-�
�tion.� The� secondary� feedback� loop� does� not� improve�
�secondary� output� accuracy� in� normal� flyback� mode,�
�where� the� main� (primary)� output� is� heavily� loaded.� In� this�
�condition,� secondary� output� accuracy� is� determined� by�
�the� secondary� rectifier� drop,� transformer� turns� ratio,� and�
�accuracy� of� the� main� output� voltage.�
�SMPS� Design� Procedure�
�Firmly� establish� the� input� voltage� range� and� maximum�
�load� current� before� choosing� a� switching� frequency�
�and� inductor� operating� point� (ripple-current� ratio).� The�
�primary� design� trade-off� lies� in� choosing� a� good� switch-�
�ing� frequency� and� inductor� operating� point,� and� the� fol-�
�trade-offs� between� size� vs.� efficiency� and� transient�
�response� vs.� output� ripple.� Low� inductor� values� pro-�
�vide� better� transient� response� and� smaller� physical�
�size,� but� also� result� in� lower� efficiency� and� higher� out-�
�put� ripple� due� to� increased� ripple� currents.� The� mini-�
�mum� practical� inductor� value� is� one� that� causes� the�
�circuit� to� operate� at� the� edge� of� critical� conduction�
�(where� the� inductor� current� just� touches� zero� with�
�every� cycle� at� maximum� load).� Inductor� values� lower�
�than� this� grant� no� further� size-reduction� benefit.� The�
�optimum� operating� point� is� usually� found� between�
�20%� and� 50%� ripple� current.� When� pulse� skipping�
�(� SKIP� low� and� light� loads),� the� inductor� value� also�
�determines� the� load-current� value� at� which�
�PFM/PWM� switchover� occurs.�
�Inductor� Selection�
�The� switching� frequency� and� inductor� operating� point�
�determine� the� inductor� value� as� follows:�
�L� =�
�V� IN� f� OSC� I� LOAD� (� MAX� )� LIR�
�For� example:� I� LOAD(MAX)� =� 5A,� V� IN� =� 12V,� V� OUT� =� 5V,�
�f� OSC� =� 300kHz,� 30%� ripple� current� or� LIR� =� 0.3:�
�lowing� four� factors� dictate� the� rest� of� the� design:�
�?� Input� Voltage� Range.� The� maximum� value�
�(V� IN(MAX)� )� must� accommodate� the� worst-case,� high�
�L� =�
�5� V� x� (� 12� V� ?� 5� V� )�
�12� V� x� 300� kHz� x� 5� A� x� 0� .� 3�
�=� 6� .� 50� μ� H�
�AC-adapter� voltage.� The� minimum� value� (V� IN(MIN)� )�
�must� account� for� the� lowest� battery� voltage� after�
�drops� due� to� connectors,� fuses,� and� battery� selector�
�switches.� If� there� is� a� choice� at� all,� lower� input� volt-�
�ages� result� in� better� efficiency.�
�?� Maximum� Load� Current.� There� are� two� values� to�
�consider.� The� peak� load� current� (I� LOAD(MAX)� )�
�determines� the� instantaneous� component� stresses�
�and� filtering� requirements� and� thus� drives� output�
�capacitor� selection,� inductor� saturation� rating,� and�
�the� design� of� the� current-limit� circuit.� The� continu-�
�ous� load� current� (I� LOAD� )� determines� the� thermal�
�Find� a� low-loss� inductor� having� the� lowest� possible� DC�
�resistance� that� fits� in� the� allotted� dimensions.� Most� induc-�
�tor� manufacturers� provide� inductors� in� standard� values,�
�such� as� 1.0μH,� 1.5μH,� 2.2μH,� 3.3μH,� etc.� Also� look� for�
�non-standard� values,� which� can� provide� a� better� compro-�
�mise� in� LIR� across� the� input� voltage� range.� If� using� a�
�swinging� inductor� (where� the� no-load� inductance�
�decreases� linearly� with� increasing� current),� evaluate� the�
�LIR� with� properly� scaled� inductance� values.� For� the�
�selected� inductance� value,� the� actual� peak-to-peak�
�inductor� ripple� current� (� Δ� I� INDUCTOR� )� is� defined� by:�
�Δ� I� INDUCTOR� =� OUT� IN� OUT�
�stresses and thus drives the selection of input�
�capacitors,� MOSFETs,� and� other� critical� heat-con-�
�tributing� components.�
�V� (� V� ?� V�
�V� IN� f� OSC� L�
�)�
�______________________________________________________________________________________�
�25�
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相关代理商/技术参数 |
参数描述 |
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| MAX17005AETP+ | 功能描述:电池管理 1.2MHz High-Perf Charger RoHS:否 制造商:Texas Instruments 电池类型:Li-Ion 输出电压:5 V 输出电流:4.5 A 工作电源电压:3.9 V to 17 V 最大工作温度:+ 85 C 最小工作温度:- 40 C 封装 / 箱体:VQFN-24 封装:Reel |
| MAX17005AETP+T | 功能描述:电池管理 1.2MHz High-Perf Charger RoHS:否 制造商:Texas Instruments 电池类型:Li-Ion 输出电压:5 V 输出电流:4.5 A 工作电源电压:3.9 V to 17 V 最大工作温度:+ 85 C 最小工作温度:- 40 C 封装 / 箱体:VQFN-24 封装:Reel |
| MAX17005BETP+ | 功能描述:电池管理 1.2MHz High-Perf Charger RoHS:否 制造商:Texas Instruments 电池类型:Li-Ion 输出电压:5 V 输出电流:4.5 A 工作电源电压:3.9 V to 17 V 最大工作温度:+ 85 C 最小工作温度:- 40 C 封装 / 箱体:VQFN-24 封装:Reel |
| MAX17005BETP+T | 功能描述:电池管理 1.2MHz High-Perf Charger RoHS:否 制造商:Texas Instruments 电池类型:Li-Ion 输出电压:5 V 输出电流:4.5 A 工作电源电压:3.9 V to 17 V 最大工作温度:+ 85 C 最小工作温度:- 40 C 封装 / 箱体:VQFN-24 封装:Reel |
| MAX17005DEVKIT+ | 功能描述:电源管理IC开发工具 Programmers, Development Systems RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
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