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参数资料
| 型号: | MAX1586CETM+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 24/30页 |
| 文件大小: | 0K |
| 描述: | IC POWER MANAGEMENT 48-TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 应用: | 手持/移动设备 |
| 电源电压: | 2.6 V ~ 5.5 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 48-WFQFN 裸露焊盘 |
| 供应商设备封装: | 48-TQFN-EP(7x7) |
| 包装: | 带卷 (TR) |
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�High-Efficiency,� Low-I� Q� PMICs� with�
�Dynamic� Core� for� PDAs� and� Smart� Phones�
�The� LSB� of� the� address� word� is� the� read/write� (R/� W� )� bit.�
�R/� W� indicates� whether� the� master� is� writing� or� reading�
�(RD/� W� 0� =� write,� RD/� W� 1� =� read).� The� MAX1586/�
�MAX1587� only� support� the� SEND� BYTE� format;� there-�
�fore,� RD/� W� is� required� to� be� 0.�
�After� receiving� the� proper� address,� the� MAX1586/�
�MAX1587� issue� an� ACK� by� pulling� SDA� low� for� one�
�clock� cycle.� The� MAX1586/MAX1587� have� two� user-�
�programmed� addresses� (Table� 3).� Address� bits� A7�
�through� A2� are� fixed,� while� A1� is� controlled� by� SRAD.�
�Connecting� SRAD� to� GND� sets� A1� =� 0.� Connecting�
�SRAD� to� IN� sets� A1� =� 1.�
�V3� Output� Ramp-Rate� Control�
�When� V3� is� dynamically� changed� with� the� serial� inter-�
�face,� the� output� voltage� changes� at� a� rate� controlled� by�
�a� capacitor� (C� RAMP� )� connected� from� RAMP� to� ground.�
�The� voltage� change� is� a� conventional� RC� exponential�
�described� by:�
�Vo(t)� =� Vo(0)� +� dV(1� –� exp(-t/(100k� Ω� C� RAMP� )))�
�A� useful� approximation� is� that� it� takes� approximately� 2.2�
�RC� time� constants� for� V3� to� move� from� 10%� to� 90%� of�
�the� voltage� difference.� For� C� RAMP� =� 1500pF,� this� time�
�is� 330μs.� For� 1V� to� 1.3V� change,� this� equates� to�
�1mV/μs.� See� the� Typical� Operating� Characteristics� for�
�examples� of� different� ramp-rate� settings.�
�The� maximum� capacitor� value� that� can� be� used� at�
�RAMP� is� 2200pF.� If� larger� values� are� used,� the� V3� ramp�
�rate� is� still� controlled� according� to� the� above� equation,�
�but� when� V3� is� first� activated,� POK� indicates� an� “in� reg-�
�ulation”� condition� before� V3� reaches� its� final� voltage.�
�The� RAMP� pin� is� effectively� the� reference� for� REG3.�
�FB3� regulates� to� 1.28� times� the� voltage� on� RAMP.�
�Design� Procedure�
�Setting� the� Output� Voltages�
�The� outputs� V1� and� V2� have� preset� output� voltages,� but�
�can� also� be� adjusted� using� a� resistor� voltage-divider.� To�
�set� V1� to� 3.3V,� connect� FB1� to� GND.� V2� can� be� preset� to�
�1.8V� or� 2.5V� on� the� MAX1586A� and� MAX1587A.� To� set�
�V2� to� 1.8V� on� the� MAX1586A� and� MAX1587A,� connect�
�FB2� to� IN.� To� set� to� 2.5V,� connect� FB2� to� GND.� V2� can�
�preset� to� 3.3V� or� 2.5V� on� the� MAX1587B.� To� set� V2� to�
�3.3V� on� the� MAX1587B,� connect� FB2� to� IN.� To� set� to�
�2.5V,� connect� FB2� to� GND.�
�To� set� V1� or� V2� to� other� than� the� preset� output� voltages,�
�connect� a� resistor� voltage-divider� from� the� output� volt-�
�age� to� the� corresponding� FB� input.� The� FB_� input� bias�
�current� is� less� than� 100nA,� so� choose� the� low-side�
�(FB_-to-GND)� resistor� (R� L� )� to� be� 100k� Ω� or� less.� Then� cal-�
�culate� the� high-side� (output-to-FB_)� resistor� (R� H� )� using:�
�R� H� =� R� L� [(V� OUT� /1.25)� –� 1]�
�The� V3� (VCC_CORE)� output� voltage� is� set� from� 0.7V� to�
�1.475V� in� 25mV� steps� by� the� I� 2� C� serial� interface.� See�
�the� Serial� Interface� section� for� details.�
�Linear� regulator� V4� provides� a� fixed� 1.3V� output� volt-�
�age.� Linear� regulator� V5� provides� a� fixed� 1.1V� output�
�voltage.� V4� and� V5� voltages� are� not� adjustable.�
�The� output� voltage� of� linear� regulator� V6� (VCC_USIM)� is�
�set� to� 0V,� 1.8V,� 2.5V,� or� 3.0V� by� the� I� 2� C� serial� interface.�
�See� the� Serial� Interface� section� for� details.�
�Linear� regulator� V7� (VCC_BATT)� tracks� the� voltage� at�
�V1� as� long� as� ON1� is� high� and� V1� is� in� regulation.� When�
�ON1� is� low� or� V1� is� not� in� regulation,� V7� switches� to� the�
�backup� battery� (V� BKBT� ).�
�Inductor� Selection�
�The� external� components� required� for� the� step-down�
�are� an� inductor,� input� and� output� filter� capacitors,� and� a�
�compensation� RC� network.�
�The� MAX1586/MAX1587� step-down� converters� provide�
�best� efficiency� with� continuous� inductor� current.� A� rea-�
�sonable� inductor� value� (L� IDEAL� )� is� derived� from:�
�L� IDEAL� =� [2(V� IN� )� x� D(1� -� D)]/(I� OUT(MAX)� x� f� OSC� )�
�This� sets� the� peak-to-peak� inductor� current� at� 1/2� the�
�DC� inductor� current.� D� is� the� duty� cycle:�
�D� =� V� OUT� /� V� IN�
�Given� L� IDEAL� ,� the� peak-to-peak� inductor� ripple� current�
�is� 0.5� x� I� OUT� .� The� peak� inductor� current� is� 1.25� x�
�I� OUT(MAX)� .� Make� sure� the� saturation� current� of� the�
�inductor� exceeds� the� peak� inductor� current� and� the�
�rated� maximum� DC� inductor� current� exceeds� the� maxi-�
�mum� output� current� (I� OUT(MAX)� ).� Inductance� values�
�larger� than� L� IDEAL� can� be� used� to� optimize� efficiency� or�
�to� obtain� the� maximum� possible� output� current.� Larger�
�inductance� values� accomplish� this� by� supplying� a�
�given� load� current� with� a� lower� inductor� peak� current.�
�Typically,� output� current� and� efficiency� are� improved�
�for� inductor� values� up� to� about� two� times� L� IDEAL� .� If� the�
�inductance� is� raised� too� much,� however,� the� inductor�
�size� may� become� too� large,� or� the� increased� inductor�
�resistance� may� reduce� efficiency� more� than� the� gain�
�derived� from� lower� peak� current.�
�Smaller� inductance� values� allow� smaller� inductor� sizes,�
�but� also� result� in� larger� peak� inductor� current� for� a�
�given� load.� Larger� output� capacitance� may� then� be�
�needed� to� suppress� the� increase� in� output� ripple�
�caused� by� larger� peak� current.�
�Capacitor� Selection�
�The� input� capacitor� in� a� DC-DC� converter� reduces� cur-�
�rent� peaks� drawn� from� the� battery� or� other� input� power�
�24�
�______________________________________________________________________________________�
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