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参数资料
| 型号: | MAX1541ETL+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 23/49页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR DIVIDER PWM 40-TQFN |
| 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: | 2 |
| 频率 - 最大: | 620kHz |
| 占空比: | 100% |
| 电源电压: | 2 V ~ 28 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 是 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 40-WFQFN 裸露焊盘 |
| 包装: | 带卷 (TR) |
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�Dual� Step-Down� Controllers� with� Saturation�
�Protection,� Dynamic� Output,� and� Linear� Regulator�
�nected� internally� to� the� fixed� 5V� linear-regulator� output�
�(LDOOUT).�
�The� 5V� bias� supply� must� provide� V� CC� (PWM� controller)�
�and� V� DD� (gate-drive� power),� so� the� maximum� current�
�drawn� is:�
�I� BIAS� =� I� CC� +� f� SW� (Q� G(LOW)� +� Q� G(HIGH)� )�
�=� 4mA� to� 50mA� (typ)�
�where� I� CC� is� 1.1mA� (typ),� f� SW� is� the� switching� frequency,�
�and� Q� G(LOW)� and� Q� G(HIGH)� are� the� MOSFET� data�
�sheet’s� total� gate-charge� specification� limits� at� V� GS� =� 5V.�
�The� V+� battery� input� and� 5V� bias� inputs� (V� CC� and� V� DD� )�
�can� be� connected� together� if� the� input� source� is� a� fixed�
�4.5V� to� 5.5V� supply.� If� the� 5V� bias� supply� powers� up�
�prior� to� the� battery� supply,� the� enable� signals� (ON1� and�
�ON2� going� from� low� to� high)� must� be� delayed� until� the�
�battery� voltage� is� present� in� order� to� ensure� startup.�
�Free-Running,� Constant� On-Time,� PWM�
�Controller� with� Input� Feed� Forward�
�The� Quick-PWM� control� architecture� is� a� pseudofixed-�
�frequency,� constant� on-time,� current-mode� regulator�
�with� voltage� feed� forward� (Figure� 2).� This� architecture�
�relies� on� the� output� filter� capacitor’s� ESR� to� act� as� a�
�current-sense� resistor,� so� the� output� ripple� voltage� pro-�
�vides� the� PWM� ramp� signal.� The� Quick-PWM� algorithm�
�is� simple:� the� high-side� switch� on-time� relies� solely� on�
�an� adjustable� one-shot� whose� pulse� width� is� inversely�
�proportional� to� input� voltage� and� directly� proportional� to�
�output� voltage.� Another� one-shot� sets� a� fixed� minimum�
�off-time� (400ns� typ).� The� controller� triggers� the� on-time�
�one-shot� when� the� error� comparator� is� low,� the� inductor�
�current� is� below� the� valley� current-limit� threshold,� and�
�the� minimum� off-time� one-shot� has� timed� out.�
�On-Time� One-Shot� (TON)�
�The� heart� of� the� PWM� core� is� the� one-shot� that� sets� the�
�high-side� switch� on-time.� This� fast,� low-jitter,� adjustable�
�one-shot� includes� circuitry� that� varies� the� on-time� in�
�response� to� the� battery� and� output� voltages.� The� high-�
�side� switch� on-time� is� inversely� proportional� to� the� bat-�
�tery� voltage� as� measured� by� the� V+� input� (V� IN� =� V+),�
�where� K� (switching� period)� is� set� by� the� TON� pin-strap�
�connection� (Table� 3).� This� algorithm� results� in� a� nearly�
�constant� switching� frequency� despite� the� lack� of� a� fixed-�
�frequency� clock� generator.� The� benefits� of� a� constant�
�switching� frequency� are� twofold:� 1)� the� frequency� can�
�be� selected� to� avoid� noise-sensitive� regions� such� as� the�
�455kHz� IF� band� and� 2)� the� inductor� ripple-current� oper-�
�ating� point� remains� relatively� constant,� resulting� in� easy�
�design� methodology� and� predictable� output� voltage� rip-�
�ple.� The� on-time� for� the� main� controller� (DH1)� is� set� 15%�
�higher� than� the� nominal� frequency� setting� (200kHz,�
�300kHz,� 420kHz,� or� 540kHz),� while� the� on-time� for� the�
�secondary� controller� (DH2)� is� set� 15%� lower� than� the�
�nominal� setting.� This� prevents� audio-frequency� “beat-�
�ing”� between� the� two� asynchronous� regulators.�
�The� on-time� one-shot� has� good� accuracy� at� the� operat-�
�ing� points� specified� in� the� Electrical� Characteristics�
�(approximately� ±12.5%� at� 540kHz� and� 420kHz� nominal�
�settings,� and� ±10%� with� the� 300kHz� and� 200kHz� set-�
�tings).� On-times� at� operating� points� far� removed� from�
�the� conditions� specified� in� the� Electrical� Characteristics�
�can� vary� over� a� wider� range.�
�The� constant� on-time� translates� only� roughly� to� a� constant�
�switching� frequency.� The� on-times� guaranteed� in� the�
�Electrical� Characteristics� are� influenced� by� resistive� loss-�
�es� and� by� switching� delays� in� the� high-side� MOSFET.�
�Resistive� losses—including� the� inductor,� both� MOSFETs,�
�and� PC� board� copper� losses� in� the� output� and� ground—�
�tend� to� raise� the� switching� frequency� as� the� load� increas-�
�es.� The� dead-time� effect� increases� the� effective� on-time,�
�reducing� the� switching� frequency� as� one� or� both� dead�
�times� add� to� the� effective� on-time.� It� occurs� only� in� PWM�
�mode� (� SKIP� =� V� CC� )� and� during� dynamic� output-voltage�
�transitions� when� the� inductor� current� reverses� at� light-� or�
�negative-load� currents.� With� reversed� inductor� current,�
�the� inductor’s� EMF� causes� LX_� to� go� high� earlier� than�
�normal,� extending� the� on-time� by� a� period� equal� to� the�
�driver� dead� time.�
�For� loads� above� the� critical� conduction� point,� where� the�
�dead-time� effect� no� longer� occurs,� the� actual� switching�
�frequency� is:�
�t� ON� (� V� IN� DROP1� DROP2� )�
�and proportional to the output voltage as measured by�
�the� OUT_� input:�
�f� SW� =�
�V� OUT_� +V� DROP1�
�+V� -� V�
�On-� Time� =� K� ?� OUT� ?�
�?� V� ?�
�?� V� IN� ?�
�where� V� DROP1� is� the� sum� of� the� parasitic� voltage� drops�
�in� the� inductor� discharge� path,� including� synchronous�
�rectifier,� inductor,� and� PC� board� resistances;� V� DROP2� is�
�the� sum� of� the� resistances� in� the� charging� path,� includ-�
�______________________________________________________________________________________�
�23�
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