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参数资料
| 型号: | MCP16301T-I/CHY |
| 厂商: | Microchip Technology |
| 文件页数: | 13/38页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK ADJ 0.6A SOT23-6 |
| 标准包装: | 1 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 2 V ~ 15 V |
| 输入电压: | 4 V ~ 30 V |
| PWM 型: | 电流模式 |
| 频率 - 开关: | 500kHz |
| 电流 - 输出: | 600mA |
| 同步整流器: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | SOT-23-6 |
| 包装: | 标准包装 |
| 供应商设备封装: | SOT-23-6 |
| 其它名称: | MCP16301T-I/CHYDKR |
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��
�
�MCP16301�
�4.2.2�
�PEAK� CURRENT� MODE� CONTROL�
�4.2.4�
�HIGH� SIDE� DRIVE�
�The� MCP16301� integrates� a� Peak� Current� Mode�
�Control� architecture,� resulting� in� superior� AC� regulation�
�while� minimizing� the� number� of� voltage� loop�
�compensation� components,� and� their� size,� for�
�integration.� Peak� Current� Mode� Control� takes� a� small�
�portion� of� the� inductor� current,� replicates� it� and�
�compares� this� replicated� current� sense� signal� with� the�
�output� of� the� integrated� error� voltage.� In� practice,� the�
�inductor� current� and� the� internal� switch� current� are�
�equal� during� the� switch-on� time.� By� adding� this� peak�
�current� sense� to� the� system� control,� the� step-down�
�power� train� system� is� reduced� from� a� 2� nd� order� to� a� 1� st�
�order.� This� reduces� the� system� complexity� and�
�increases� its� dynamic� performance.�
�For� Pulse-Width� Modulation� (PWM)� duty� cycles� that�
�exceed� 50%,� the� control� system� can� become� bimodal�
�where� a� wide� pulse� followed� by� a� short� pulse� repeats�
�instead� of� the� desired� fixed� pulse� width.� To� prevent� this�
�mode� of� operation,� an� internal� compensating� ramp� is�
��4.2.3� PULSE-WIDTH� MODULATION�
�(PWM)�
�The� internal� oscillator� periodically� starts� the� switching�
�period,� which� in� MCP16301’s� case� occurs� every� 2� μs�
�or� 500� kHz.� With� the� integrated� switch� turned� on,� the�
�inductor� current� ramps� up� until� the� sum� of� the� current�
�sense� and� slope� compensation� ramp� exceeds� the� inte-�
�grated� error� amplifier� output.� The� error� amplifier� output�
�slews� up� or� down� to� increase� or� decrease� the� inductor�
�peak� current� feeding� into� the� output� LC� filter.� If� the� reg-�
�ulated� output� voltage� is� lower� than� its� target,� the� invert-�
�ing� error� amplifier� output� rises.� This� results� in� an�
�increase� in� the� inductor� current� to� correct� for� errors� in�
�the� output� voltage.� The� fixed� frequency� duty� cycle� is�
�The� MCP16301� features� an� integrated� high-side�
�N-Channel� MOSFET� for� high� efficiency� step-down�
�power� conversion.� An� N-Channel� MOSFET� is� used� for�
�its� low� resistance� and� size� (instead� of� a� P-Channel�
�MOSFET).� The� N-Channel� MOSFET� gate� must� be�
�driven� above� its� source� to� fully� turn� on� the� transistor.� A�
�gate-drive� voltage� above� the� input� is� necessary� to� turn�
�on� the� high� side� N-Channel.� The� high� side� drive� voltage�
�should� be� between� 3.0V� and� 5.5V.� The� N-Channel�
�source� is� connected� to� the� inductor� and� Schottky� diode,�
�or� switch� node.� When� the� switch� is� off,� the� inductor� cur-�
�rent� flows� through� the� Schottky� diode,� providing� a� path�
�to� recharge� the� boost� cap� from� the� boost� voltage�
�source,� typically� the� output� voltage� for� 3.0V� to� 5.0V� out-�
�put� applications.� A� boost-blocking� diode� is� used� to� pre-�
�vent� current� flow� from� the� boost� cap� back� into� the�
�output� during� the� internal� switch-on� time.� Prior� to�
�startup,� the� boost� cap� has� no� stored� charge� to� drive� the�
�switch.� An� internal� regulator� is� used� to� “pre-charge”� the�
�boost� cap.� Once� pre-charged,� the� switch� is� turned� on�
�and� the� inductor� current� flows.� When� the� switch� turns�
�off,� the� inductor� current� free-wheels� through� the�
�Schottky� diode,� providing� a� path� to� recharge� the� boost�
�cap.� Worst� case� conditions� for� recharge� occur� when�
�the� switch� turns� on� for� a� very� short� duty� cycle� at� light�
�load,� limiting� the� inductor� current� ramp.� In� this� case,�
�there� is� a� small� amount� of� time� for� the� boost� capacitor�
�to� recharge.� For� high� input� voltages� there� is� enough�
�pre-charge� current� to� replace� the� boost� cap� charge.� For�
�input� voltages� above� 5.5V� typical,� the� MCP16301�
�device� will� regulate� the� output� voltage� with� no� load.�
�After� starting,� the� MCP16301� will� regulate� the� output�
�voltage� until� the� input� voltage� decreases� below� 4V.� See�
��voltage,� output� voltage� and� load.�
�terminated� when� the� sensed� inductor� peak� current,�
�4.2.5�
�ALTERNATIVE� BOOST� BIAS�
�summed� with� the� internal� slope� compensation,�
�exceeds� the� output� voltage� of� the� error� amplifier.� The�
�PWM� latch� is� set� by� turning� off� the� internal� switch� and�
�preventing� it� from� turning� on� until� the� beginning� of� the�
�next� cycle.� An� overtemperature� signal,� or� boost� cap�
�undervoltage,� can� also� reset� the� PWM� latch� to� asyn-�
�chronously� terminate� the� cycle.�
�?� 2011� Microchip� Technology� Inc.�
�For� 3.0V� to� 5.0V� output� voltage� applications,� the� boost�
�supply� is� typically� the� output� voltage.� For� applications�
�with� 3.0V� <� V� OUT� <� 5.0V,� an� alternative� boost� supply�
�can� be� used.�
�Alternative� boost� supplies� can� be� from� the� input,� input�
�derived,� output� derived� or� an� auxiliary� system� voltage.�
�For� low� voltage� output� applications� with� unregulated�
�input� voltage,� a� shunt� regulator� derived� from� the� input�
�can� be� used� to� derive� the� boost� supply.� For�
�applications� with� high� output� voltage� or� regulated� high�
�input� voltage,� a� series� regulator� can� be� used� to� derive�
�the� boost� supply.�
�DS25004A-page� 13�
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