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参数资料
| 型号: | MAX15058EWL+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 12/21页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK SYNC ADJ 3A 9WLP |
| 产品培训模块: | Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 0.6 V ~ 5.17 V |
| 输入电压: | 2.7 V ~ 5.5 V |
| PWM 型: | 电流模式 |
| 频率 - 开关: | 1MHz |
| 电流 - 输出: | 3A |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 9-WFBGA,WLBGA |
| 包装: | 带卷 (TR) |
| 供应商设备封装: | 9-WLP(1.5x1.5) |
��
�
�High-Efficiency,� 3A,� Current-Mode�
�Synchronous,� Step-Down� Switching� Regulator�
�R1� =� R2� � ?� OUT� ?� 1� ?�
�� ?� 1� ?� OUT� ?�
�L� =�
�Error Amplifier�
�A� high-gain� error� amplifier� provides� accuracy� for� the�
�voltage-feedback� loop� regulation.� Connect� the� neces-�
�sary� compensation� network� between� COMP� and� GND�
�(see� the� Compensation� Design� Guidelines� section).� The�
�error-amplifier� transconductance� is� 1.5mS� (typ).� COMP�
�clamp� low� is� set� to� 0.94V� (typ),� just� below� the� slope� ramp�
�compensation� valley,� helping� COMP� to� rapidly� return� to�
�the� correct� set� point� during� load� and� line� transients.�
�PWM� Comparator�
�The� PWM� comparator� compares� COMP� voltage� to� the�
�current-derived� ramp� waveform� (LX� current� to� COMP�
�voltage� transconductance� value� is� 18A/V� typ).� To� avoid�
�instability� due� to� subharmonic� oscillations� when� the� duty�
�cycle� is� around� 50%� or� higher,� a� slope� compensation�
�ramp� is� added� to� the� current-derived� ramp� waveform.�
�Confirm� the� compensation� ramp� slope� (0.3V� x� 1MHz�
�=� 0.3V/� F� s)� is� equivalent� to� half� the� inductor� current�
�downslope� in� the� worst� case� (load� 3A,� current� ripple�
�30%� and� maximum� duty-cycle� operation� of� 94%).� The�
�slope� compensation� ramp� valley� is� set� to� 1.15V� (typ).�
�Overcurrent� Protection� and� Hiccup�
�When� the� converter� output� is� shorted� or� the� device� is�
�overloaded,� each� high-side� MOSFET� current-limit� event�
�(5A� typ)� turns� off� the� high-side� MOSFET� and� turns� on� the�
�low-side� MOSFET.� On� each� current-limit� event� a� 3-bit�
�counter� is� incremented.� The� counter� is� reset� after� three�
�consecutive� high-side� MOSFETs� turn� on� without� reach-�
�ing� current� limit.� If� the� current-limit� condition� persists,�
�the� counter� fills� up� reaching� eight� events.� The� control�
�logic� then� discharges� SS/REFIN,� stops� both� high-side�
�and� low-side� MOSFETs,� and� waits� for� a� hiccup� period�
�(1024� clock� cycles� typ)� before� attempting� a� new� soft-�
�start� sequence.� The� hiccup� mode� is� also� enabled� during�
�soft-start� time.�
�Thermal-Shutdown� Protection�
�The� MAX15058� contains� an� internal� thermal� sensor� that�
�limits� the� total� power� dissipation� to� protect� the� device� in�
�the� event� of� an� extended� thermal� fault� condition.� When�
�the� die� temperature� exceeds� +150� N� C� (typ),� the� thermal�
�sensor� shuts� down� the� device,� turning� off� the� DC-DC�
�converter� to� allow� the� die� to� cool.� After� the� die� tempera-�
�ture� falls� by� 20� N� C� (typ),� the� device� restarts,� following� the�
�soft-start� sequence.�
�Skip� Mode� Operation�
�The� MAX15058� operates� in� skip� mode� when� SKIP� is� con-�
�nected� to� EN.� When� in� skip� mode,� LX� output� becomes�
�high� impedance� when� the� inductor� current� falls� below�
�200mA� (typ).� The� inductor� current� does� not� become�
�negative.� If� during� a� clock� cycle� the� inductor� current� falls�
�below� the� 200mA� threshold� (during� off-time),� the� low� side�
�turns� off.� At� the� next� clock� cycle,� if� the� output� voltage� is�
�above� set� point,� the� PWM� logic� keeps� both� high-side�
�and� low-side� MOSFETs� off.� If� instead� the� output� voltage�
�is� below� the� set� point,� the� PWM� logic� drives� the� high-�
�side� on� for� a� minimum� fixed� on-time� (300ns� typ).� In� this�
�way� the� system� can� skip� cycles,� reducing� frequency� of�
�operations,� and� switches� only� as� needed� to� service� load�
�at� the� cost� of� an� increase� in� output� voltage� ripple� (see�
�the� Skip� Mode� Frequency� and� Output� Ripple� section).� In�
�skip� mode,� power� dissipation� is� reduced� and� efficiency�
�is� improved� at� light� loads� because� power� MOSFETs� do�
�not� switch� at� every� clock� cycle.�
�Applications� Information�
�Setting� the� Output� Voltage�
�The� MAX15058� output� voltage� is� adjustable� from� 0.6V�
�up� to� 94%� of� V� IN� by� connecting� FB� to� the� center� tap� of� a�
�resistor-divider� between� the� output� and� GND� (Figure� 1).�
�Choose� R1� and� R2� so� that� the� DC� errors� due� to� the� FB�
�input� bias� current� (� Q� 500nA)� do� not� affect� the� output� volt-�
�age� accuracy.� With� lower� value� resistors,� the� DC� error�
�is� reduced,� but� the� amount� of� power� consumed� in� the�
�resistor-divider� increases.� A� typical� value� for� R2� is� 10k� I� ,�
�but� values� between� 5k� I� and� 50k� I� are� acceptable.� Once�
�R2� is� chosen,� calculate� R1� using:�
�?� V� ?�
�?� V� FB� ?�
�where� the� feedback� threshold� voltage,� V� FB� =� 0.6V� (typ).�
�When� regulating� for� an� output� of� 0.6V� in� skip� mode,� short�
�FB� to� OUT� and� keep� R2� connected� from� FB� to� GND.�
�Inductor� Selection�
�A� high-valued� inductor� results� in� reduced� inductor� ripple�
�current,� leading� to� a� reduced� output� ripple� voltage.�
�However,� a� high-valued� inductor� results� in� either� a� larger�
�physical� size� or� a� high� series� resistance� (DCR)� and� a�
�lower� saturation� current� rating.� Typically,� choose� an�
�inductor� value� to� produce� a� current� ripple� equal� to� 30%�
�of� load� current.� Choose� the� inductor� with� the� following�
�formula:�
�V� OUT� ?� V� ?�
�f� SW� � LIR� � I� LOAD� ?� V� IN� ?�
�where� f� SW� is� the� internally� fixed� 1MHz� switching� frequen-�
�cy,� and� LIR� is� the� desired� inductor� current� ratio� (typically�
�12�
�_____________________________________________________________________________________�
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