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MAX15002�
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Dual-Output� Buck� Controller� with�
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Tracking/Sequencing�
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Internal� Undervoltage� Lockout� (UVLO)�
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V� IN� must� exceed� the� default� UVLO� threshold� before� any�
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operation� can� commence.� The� UVLO� circuitry� keeps� the�
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MOSFET� drivers,� oscillator,� and� all� the� internal� circuitry�
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shut� down� to� reduce� current� consumption.� The� UVLO�
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rising� threshold� is� 4.05V� with� 350mV� hysteresis.�
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Digital� Soft-Start/Soft-Stop�
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The� MAX15002� soft-start� feature� allows� the� load� voltage�
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to� ramp� up� in� a� controlled� manner,� eliminating� output-�
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voltage� overshoot.� Soft-start� begins� after� V� IN� exceeds�
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the� undervoltage� lockout� threshold� and� the� enable�
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input� is� above� 1.24V.� The� soft-start� circuitry� gradually�
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ramps� up� the� reference� voltage.� This� controls� the� rate�
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of� rise� of� the� output� voltage� and� reduces� input� surge�
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currents� during� startup.� The� soft-start� duration� is� 2048�
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clock� cycles.� The� output� voltage� is� incremented�
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through� 64� equal� steps.� The� output� reaches� regulation�
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when� soft-start� is� completed,� regardless� of� output�
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capacitance� and� load.�
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Soft-stop� commences� when� the� enable� input� falls�
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below� 1.12V.� The� soft-stop� circuitry� ramps� down� the�
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reference� voltage� controlling� the� output� voltage� rate� of�
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fall.� The� output� voltage� is� decremented� through� 64�
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equal� steps� in� 2048� clock� cycles.�
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Internal� Linear� Regulator� (REG)�
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REG� is� the� output� terminal� of� a� 5V� LDO� powered� from� IN�
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which� provides� power� to� the� IC.� Connect� REG� externally�
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to� DREG_� to� provide� power� for� the� low-side� MOSFET�
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gate� driver.� Bypass� REG� to� SGND� with� a� minimum� 2.2μF�
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ceramic� capacitor.� Place� the� capacitor� physically� close�
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to� the� MAX15002� to� provide� good� bypassing.� REG� is�
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intended� for� powering� only� the� internal� circuitry� and�
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should� not� be� used� to� supply� power� to� external� loads.�
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REG� can� source� up� to� 120mA.� This� current,� I� REG� ,�
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includes� quiescent� current� (I� Q� )� and� gate� drive� current�
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(I� DREG_� ):�
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I� REG� =� I� Q� +� [f� SW� x� Σ� (Q� GHS_� +� Q� GLS_� )]�
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where� Q� GHS_� +� Q� GLS_� is� the� total� gate� charge� of� each�
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of� the� respective� high-� and� low-side� external� MOSFETs�
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at� V� GATE� =� 5V.� f� SW� is� the� switching� frequency� of� the�
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converter� and� I� Q� is� the� quiescent� current� of� the� device�
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at� the� switching� frequency.�
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Maxim� Integrated�
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MOSFET� Gate� Drivers�
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DREG_� is� the� supply� input� for� the� low-side� MOSFET� dri-�
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ver.� Connect� DREG_� to� REG� externally.� Everytime� the�
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low-side� MOSFET� switches� on,� high� peak� current� is�
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drawn� from� DREG_� for� a� short� amount� of� time.� Adding�
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an� RC� filter� (1� ?� to� 3.3� ?� and� 2.2μF//0.1μF� ceramic�
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capacitors� are� typical)� from� REG� to� DREG_� filters� out�
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high-peak� currents.�
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BST_� supplies� the� power� for� the� high-side� MOSFET� dri-�
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vers.� Connect� the� bootstrap� diode� from� BST_� to� DREG_�
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(anode� at� DREG_� and� cathode� at� BST_).� Connect� a�
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bootstrap� 0.1μF� or� higher� ceramic� capacitor� between�
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BST_� and� LX_.� Though� not� always� necessary,� it� may� be�
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useful� to� insert� a� small� resistor� (4.7� ?� to� 22� ?� )� in� series�
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with� the� BST_� pin� and� the� cathode� of� the� bootstrap�
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diode� for� additional� noise� immunity.�
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The� high-side� (DH_)� and� low-side� (DL_)� drivers� drive�
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the� gates� of� the� external� n-channel� MOSFETs.� The� dri-�
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vers’� 2A� peak� source-� and� sink-current� capability� pro-�
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vides� ample� drive� for� the� fast� rise� and� fall� times� of� the�
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switching� MOSFETs.� Faster� rise� and� fall� times� result� in�
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reduced� switching� losses.�
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The� gate� driver� circuitry� also� provides� a� break-before-�
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make� time� (20ns� typ)� to� prevent� shoot-through� currents�
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during� transition.�
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Oscillator/Synchronization� Input/Phase�
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Staggering� (RT,� SYNC,� PHASE)�
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Use� an� external� resistor� at� RT� to� program� the�
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MAX15002� switching� frequency� from� 200kHz� to�
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2.2MHz.� Choose� the� appropriate� resistor� at� RT� to� cal-�
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culate� the� desired� output� switching� frequency� (f� SW� ):�
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f� SW� (Hz)� =� 1.5� x� 10� 11� /(R� RT� +� 2000)� ?�
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Connect� an� external� clock� at� SYNC� for� external� clock�
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synchronization.� A� rising� clock� edge� on� SYNC� is� inter-�
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preted� as� a� synchronization� input.� If� the� SYNC� signal� is�
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lost,� the� internal� oscillator� takes� control� of� the� switching�
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rate,� returning� the� switching� frequency� to� that� set� by�
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R� RT� .� This� maintains� output� regulation� even� with� intermit-�
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tent� SYNC� signals.� For� proper� synchronization,� the�
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external� frequency� must� be� at� least� 20%� higher� than�
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twice� the� frequency� programmed� through� the� RT� input.�
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The� switching� frequency� is� 1/2� the� SYNC� frequency.�
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Connect� SYNC� to� SGND� when� not� used.�
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Connect� PHASE� to� SGND� for� 180°� out-of-phase� opera-�
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tion� between� the� controllers.� Connect� PHASE� to� REG�
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for� in-phase� operation.�
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13�
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