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| 型号: | NCP1575D |
| 厂商: | ON Semiconductor |
| 文件页数: | 10/16页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 8-SOIC |
| 产品变化通告: | Product Obsolescence 11/Feb/2009 |
| 标准包装: | 98 |
| PWM 型: | 电流/电压模式,V²? |
| 输出数: | 1 |
| 频率 - 最大: | 320kHz |
| 电源电压: | 9 V ~ 20 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | 0°C ~ 125°C |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 管件 |
��
�
�NCP1575�
�APPLICATION� INFORMATION�
�THEORY� OF� OPERATION�
�The� NCP1575� is� a� simple,� synchronous,� fixed?frequency,�
�low?voltage� buck� controller� using� the� V� 2� control� method.�
�V� 2� Control� Method�
�The� V� 2� control� method� uses� a� ramp� signal� generated� by�
�the� ESR� of� the� output� capacitors.� This� ramp� is� proportional�
�to� the� ac� current� through� the� main� inductor� and� is� offset� by�
�the� dc� output� voltage.� This� control� scheme� inherently�
�compensates� for� variation� in� either� line� or� load� conditions,�
�since� the� ramp� signal� is� generated� from� the� output� voltage�
�itself.� The� V� 2� method� differs� from� traditional� techniques�
�such� as� voltage� mode� control,� which� generates� an� artificial�
�ramp,� and� current� mode� control,� which� generates� a� ramp�
�using� the� inductor� current.�
�The� error� signal� loop� can� have� a� low� crossover� frequency,�
�since� the� transient� response� is� handled� by� the� ramp� signal�
�loop.� The� main� purpose� of� this� ‘slow’� feedback� loop� is� to�
�provide� dc� accuracy.� Noise� immunity� is� significantly�
�improved,� since� the� error� amplifier� bandwidth� can� be� rolled�
�off� at� a� low� frequency.� Enhanced� noise� immunity� improves�
�remote� sensing� of� the� output� voltage,� since� the� noise�
�associated� with� long� feedback� traces� can� be� effectively�
�filtered.�
�Line� and� load� regulation� are� drastically� improved� because�
�there� are� two� independent� control� loops.� A� voltage� mode�
�controller� relies� on� the� change� in� the� error� signal� to�
�compensate� for� a� deviation� in� either� line� or� load� voltage.�
�This� change� in� the� error� signal� causes� the� output� voltage� to�
�change� corresponding� to� the� gain� of� the� error� amplifier,�
�which� is� normally� specified� as� line� and� load� regulation.� A�
�RAMP�
�?�
�PWM�
�+�
�GATE(H)�
�GATE(L)�
�Output�
�Voltage�
�current� mode� controller� maintains� a� fixed� error� signal� during�
�line� transients,� since� the� slope� of� the� ramp� signal� changes� in�
�this� case.� However,� regulation� of� load� transients� still� requires�
�a� change� in� the� error� signal.� The� V� 2� method� of� control�
�maintains� a� fixed� error� signal� for� both� line� and� load� variation,�
�since� the� ramp� signal� is� affected� by� both� line� and� load.�
�The� stringent� load� transient� requirements� of� modern�
�microprocessors� require� the� output� capacitors� to� have� very�
�COMP�
�Slope�
�Compensation�
�Error�
�Signal�
�Error�
�Amplifier�
�?�
�+�
�V� FB�
�Reference�
�Voltage�
�low� ESR.� The� resulting� shallow� slope� in� the� output� ripple� can�
�lead� to� pulse� width� jitter� and� variation� caused� by� both� random�
�and� synchronous� noise.� A� ramp� waveform� generated� in� the�
�oscillator� is� added� to� the� ramp� signal� from� the� output� voltage�
�to� provide� the� proper� voltage� ramp� at� the� beginning� of� each�
�Figure� 20.� V� 2� Control� with� Slope� Compensation�
�The� V� 2� control� method� is� illustrated� in� Figure� 20.� The�
�output� voltage� generates� both� the� error� signal� and� the� ramp�
�signal.� Since� the� ramp� signal� is� simply� the� output� voltage,� it�
�is� affected� by� any� change� in� the� output,� regardless� of� the�
�origin� of� that� change.� The� ramp� signal� also� contains� the� DC�
�portion� of� the� output� voltage,� allowing� the� control� circuit� to�
�drive� the� main� switch� from� 0%� to� 100%� duty� cycle� as�
�required.�
�A� variation� in� line� voltage� changes� the� current� ramp� in� the�
�inductor,� which� causes� the� V� 2� control� scheme� to� compensate�
�the� duty� cycle.� Since� any� variation� in� inductor� current�
�modifies� the� ramp� signal,� as� in� current� mode� control,� the� V� 2�
�control� scheme� offers� the� same� advantages� in� line� transient�
�response.�
�A� variation� in� load� current� will� affect� the� output� voltage,�
�modifying� the� ramp� signal.� A� load� step� immediately� changes�
�the� state� of� the� comparator� output,� which� controls� the� main�
�switch.� The� comparator� response� time� and� the� transition�
�speed� of� the� main� switch� determine� the� load� transient�
�response.� Unlike� traditional� control� methods,� the� reaction�
�time� to� the� output� load� step� is� not� related� to� the� crossover�
�frequency� of� the� error� signal� loop.�
�switching� cycle.� This� slope� compensation� increases� the� noise�
�immunity,� particularly� at� duty� cycles� above� 50%.�
�Startup�
�The� NCP1575� features� a� programmable� soft?start�
�function,� which� is� implemented� through� the� error� amplifier�
�and� the� external� compensation� capacitor.� This� feature�
�prevents� stress� to� the� power� components� and� limits� output�
�voltage� overshoot� during� startup.� As� power� is� applied� to� the�
�regulator,� the� NCP1575� undervoltage� lockout� circuit� (UVL)�
�monitors� the� IC’s� supply� voltage� (V� CC� ).� The� UVL� circuit�
�holds� the� GATE(H)� output� low� and� the� GATE(L)� output�
�high� until� V� CC� exceeds� the� 8.5� V� threshold.� A� hysteresis�
�function� of� 1.0� V� improves� noise� immunity.� The�
�compensation� capacitor� connected� to� the� COMP� pin� is�
�charged� by� a� 30� m� A� current� source.� When� the� capacitor�
�voltage� exceeds� the� 0.465� V� offset� of� the� PWM� comparator,�
�the� PWM� control� loop� will� allow� switching� to� occur.� The�
�upper� gate� driver� GATE(H)� is� activated,� turning� on� the� upper�
�MOSFET.� The� current� ramps� up� through� the� main� inductor�
�and� linearly� powers� the� output� capacitors� and� load.� When�
�the� regulator� output� voltage� exceeds� the� COMP� pin� voltage�
�minus� the� 0.465� V� PWM� comparator� offset� threshold� and�
�the� artificial� ramp,� the� PWM� comparator� terminates� the�
�initial� pulse.�
�http://onsemi.com�
�10�
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