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参数资料
| 型号: | LTC1700EMS#TRPBF |
| 厂商: | Linear Technology |
| 文件页数: | 10/16页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BST PWM CM 10-MSOP |
| 标准包装: | 2,500 |
| PWM 型: | 电流模式 |
| 输出数: | 1 |
| 频率 - 最大: | 680kHz |
| 占空比: | 92% |
| 电源电压: | 0.9 V ~ 6 V |
| 降压: | 无 |
| 升压: | 是 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 10-TFSOP,10-MSOP(0.118",3.00mm 宽) |
| 包装: | 带卷 (TR) |
��
�
�LTC1700�
�APPLICATIO� N� S� I� N� FOR� M� ATIO� N�
�L� MIN� ≥� V� IN� (� MAX� )� ?� ?�
�To eliminate this subharmonic oscillation, a compensat-�
�ing� ramp� is� added� internally� to� the� LTC1700� on� the�
�inductor� current� waveform� when� the� duty� cycle� exceeds�
�5%.� This� scheme,� known� as� slope� compensation,� makes�
�the� loop� perceive� that� there� is� more� inductor� current� than�
�it� actually� has.� As� a� result,� the� maximum� current� capability�
�of� the� regulator� is� reduced.� This� reduction� is� proportional�
�to� the� duty� cycle� and� is� shown� in� Figure� 5.� Hence� for�
�applications� that� operate� at� high� duty� cycles,� the�
�N-channel� MOSFET� chosen� should� have� a� lower� R� DS(ON)�
�to� make� up� for� this� reduction� (See� Design� Example).�
�1.2�
�?� DC� ?�
�?� f� ?� I� L� ?�
�With� Burst� Mode� operation� enabled� on� the� LTC1700,� the�
�ripple� current� is� normally� set� such� that� the� inductor�
�current� is� continuous� during� burst� periods.� Remember�
�that� during� bursting,� the� peak� current� is� clamped� at�
�approximately:�
�I� BURST(PEAK)� ?� 36mV/R� DS(ON)�
�Hence� the� peak-to-peak� ripple� selected� for� optimal� burst�
�mode� operation� should� not� exceed� I� BURST(PEAK)� .� This�
�implies� a� minimum� inductance� of:�
�(� f� )(� 0� .� 66� )� ?� ?�
�1.0�
�0.8�
�0.6�
�L� MINBURST� =�
�V� IN� (� MAX� )� (� DC� )�
�?� I� OMAX� ?�
�?� 1� –� DC� ?�
�0.4�
�0.2�
�In� applications� that� invoke� Burst� Mode� operation,� the�
�inductor� should� be� chosen� so� it� has� low� ripple� (0.4I� OMAX� )�
�current� during� heavy� load� and� continuous� operation� dur-�
�0�
�0�
�10�
�20�
�30� 40� 50�
�DUTY� CYCLE� (%)�
�60�
�70�
�ing� bursting.� The� criteria� for� selecting� which� equation� to�
�use� is:�
�?� I� L� =� V� IN� ?�
�?� fL� ?�
�1700� F05�
�Figure� 5.� Maximum� Output� Current� vs� Duty� Cycle�
�Inductor� Value� Selection�
�Given� the� input� voltage,� inductor� value� and� operating�
�frequency,� the� ripple� current� can� be� calculated:�
�?� DC� ?�
�?�
�Lower� ripple� current� reduces� core� losses� in� the� inductor,�
�ESR� losses� in� the� output� capacitors� and� output� voltage�
�ripple.� Thus,� highest� efficiency� operation� is� obtained� at�
�low� frequency� with� small� ripple� current.� To� achieve� this,�
�however,� requires� a� larger� inductor.�
�A� reasonable� starting� point� is� to� choose� a� ripple� current�
�that� is� about� 40%� of� I� O(MAX)� .� Note� that� the� largest� ripple�
�current� occurs� at� the� highest� V� IN� .� To� guarantee� that� ripple�
�current� does� not� exceed� a� specified� maximum,� the� induc-�
�tor� should� be� chosen� according� to:�
�Use� L� MIN� for� Duty� Cycle� >� 36%�
�Use� L� MINBURST� for� Duty� Cycle� ≤� 36%�
�A� smaller� value� than� L� MIN� could� be� used� in� the� circuit;�
�however,� the� inductor� current� will� not� be� continuous�
�during� burst� periods.� The� advantage� of� using� a� smaller�
�inductance� than� L� MIN� is� primarily� size.� The� disadvantage� is�
�higher� output� ripple.�
�Inductor� Core� Selection�
�Once� the� value� for� L� is� known,� the� type� of� inductor� must� be�
�selected.� High� efficiency� converters� generally� cannot� af-�
�ford� the� core� loss� found� in� low� cost� powdered� iron� cores,�
�forcing� the� use� of� more� expensive� ferrite,� molypermalloy,�
�or� Kool� M� μ� ?� cores.� Actual� core� loss� is� independent� of� core�
�size� for� a� fixed� inductor� value,� but� it� is� very� dependent� on�
�inductance� selected.� As� inductance� increases,� core� losses�
�go� down.� Unfortunately,� increased� inductance� requires�
�more� turns� of� wire� and� therefore� copper� losses� will�
�increase.� Ferrite� designs� have� very� low� core� losses� and� are�
�Kool� M� μ� is� a� registered� trademark� of� Magnetics,� Inc.�
�1700fa�
�10�
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