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| 型号: | LTC1735CGN#TRPBF |
| 厂商: | Linear Technology |
| 文件页数: | 21/32页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM CM 16-SSOP |
| 标准包装: | 2,500 |
| PWM 型: | 电流模式 |
| 输出数: | 1 |
| 频率 - 最大: | 335kHz |
| 占空比: | 99.4% |
| 电源电压: | 4 V ~ 30 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 ~ 85°C |
| 封装/外壳: | 16-SSOP(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
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�LTC1735�
�APPLICATIO� S� I� FOR� ATIO�
�Although� all� dissipative� elements� in� the� circuit� produce�
�losses,� 4� main� sources� usually� account� for� most� of� the�
�losses� in� LTC1735� circuits:� 1)� V� IN� current,� 2)� INTV� CC�
�current,� 3)� I� 2� R� losses,� 4)� Topside� MOSFET� transition�
�losses.�
�1)� The� V� IN� current� is� the� DC� supply� current� given� in� the�
�electrical� characteristics� which� excludes� MOSFET� driver�
�and� control� currents.� V� IN� current� results� in� a� small� (<0.1%)�
�loss� that� increases� with� V� IN� .�
�2)� INTV� CC� current� is� the� sum� of� the� MOSFET� driver� and�
�control� currents.� The� MOSFET� driver� current� results� from�
�switching� the� gate� capacitance� of� the� power� MOSFETs.�
�Each� time� a� MOSFET� gate� is� switched� from� low� to� high� to�
�low� again,� a� packet� of� charge� dQ� moves� from� INTV� CC� to�
�ground.� The� resulting� dQ/dt� is� a� current� out� of� INTV� CC� that�
�is� typically� much� larger� than� the� control� circuit� current.� In�
�continuous� mode,� I� GATECHG� =� f(Q� T� +Q� B� ),� where� Q� T� and� Q� B�
�are� the� gate� charges� of� the� topside� and� bottom-side�
�MOSFETs.�
�Supplying� INTV� CC� power� through� the� EXTV� CC� switch� input�
�from� an� output-derived� or� other� high� efficiency� source� will�
�scale� the� V� IN� current� required� for� the� driver� and� control�
�circuits� by� a� factor� of� (Duty� Cycle)/(Efficiency).� For� ex-�
�ample,� in� a� 20V� to� 5V� application,� 10mA� of� INTV� CC� current�
�results� in� approximately� 3mA� of� V� IN� current.� This� reduces�
�the� mid-current� loss� from� 10%� or� more� (if� the� driver� was�
�powered� directly� from� V� IN� )� to� only� a� few� percent.�
�3)� I� 2� R� losses� are� predicted� from� the� DC� resistances� of� the�
�MOSFET,� inductor� and� current� shunt.� In� continuous� mode�
�the� average� output� current� flows� through� L� and� R� SENSE� ,�
�but� is� “chopped”� between� the� topside� main� MOSFET� and�
�the� synchronous� MOSFET.� If� the� two� MOSFETs� have�
�approximately� the� same� R� DS(ON)� ,� then� the� resistance� of�
�one� MOSFET� can� simply� be� summed� with� the� resistances�
�of� L� and� R� SENSE� to� obtain� I� 2� R� losses.� For� example,� if� each�
�R� DS(ON)� =� 0.03� ?� ,� R� L� =� 0.05� ?� and� R� SENSE� =� 0.01� ?� ,� then�
�the� total� resistance� is� 0.09� ?� .� This� results� in� losses� ranging�
�from� 2%� to� 9%� as� the� output� current� increases� from� 1A� to�
�5A� for� a� 5V� output,� or� a� 3%� to� 14%� loss� for� a� 3.3V� output.�
�Effeciency� varies� as� the� inverse� square� of� V� OUT� for� the�
�same� external� components� and� output� power� level.� I� 2� R�
�losses� cause� the� efficiency� to� drop� at� high� output� currents.�
�4)� Transition� losses� apply� only� to� the� topside� MOSFET(s)�
�and� only� become� significant� when� operating� at� high� input�
�voltages� (typically� 12V� or� greater).� Transition� losses� can�
�be� estimated� from:�
�Transition� Loss� =� (1.7)� V� IN2� I� O(MAX)� C� RSS� f�
�Other� “hidden”� losses� such� as� copper� trace� and� internal�
�battery� resistances� can� account� for� an� additional� 5%� to�
�10%� efficiency� degradation� in� portable� systems.� It� is� very�
�important� to� include� these� “system”� level� losses� in� the�
�design� of� a� system.� The� internal� battery� and� fuse� resis-�
�tance� losses� can� be� minimized� by� making� sure� that� C� IN� has�
�adequate� charge� storage� and� very� low� ESR� at� the� switch-�
�ing� frequency.� A� 25W� supply� will� typically� require� a�
�minimum� of� 20� μ� F� to� 40� μ� F� of� capacitance� having� a� maxi-�
�mum� of� 0.01� ?� to� 0.02� ?� of� ESR.� Other� losses� including�
�Schottky� conduction� losses� during� dead-time� and� induc-�
�tor� core� losses� generally� account� for� less� than� 2%� total�
�additional� loss.�
�Checking� Transient� Response�
�The� regulator� loop� response� can� be� checked� by� looking� at�
�the� load� current� transient� response.� Switching� regulators�
�take� several� cycles� to� respond� to� a� step� in� load� current.�
�When� a� load� step� occurs,� V� OUT� shifts� by� an� amount� equal�
�to� ?� I� LOAD� (ESR),� where� ESR� is� the� effective� series� resis-�
�tance� of� C� OUT� .� ?� I� LOAD� also� begins� to� charge� or� discharge�
�C� OUT� ,� generating� the� feedback� error� signal� that� forces� the�
�regulator� to� adapt� to� the� current� change� and� return� V� OUT�
�to� its� steady-state� value.� During� this� recovery� time� V� OUT�
�can� be� monitored� for� excessive� overshoot� or� ringing,�
�which� would� indicate� a� stability� problem.� OPTI-LOOP�
�compensation� allows� the� transient� response� to� be� opti-�
�mized� over� a� wide� range� of� output� capacitance� and� ESR�
�values.� The� availability� of� the� I� TH� pin� not� only� allows�
�optimization� of� control� loop� behavior� but� also� provides� a�
�DC� coupled� and� AC� filtered� closed� loop� response� test�
�point.� The� DC� step,� rise� time� and� settling� at� this� test� point�
�truly� reflects� the� closed� loop� response.� Assuming� a� pre-�
�dominantly� second� order� system,� phase� margin� and/or�
�damping� factor� can� be� estimated� using� the� percentage� of�
�overshoot� seen� at� this� pin.� The� bandwidth� can� also� be�
�estimated� by� examining� the� rise� time� at� the� pin.� The� I� TH�
�external� components� shown� in� the� Figure� 1� circuit� will�
�provide� an� adequate� starting� point� for� most� applications.�
�1735fc�
�21�
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相关代理商/技术参数 |
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| LTC1735CS | 功能描述:IC REG CTRLR BUCK PWM CM 16-SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:500kHz 占空比:96% 电源电压:4 V ~ 36 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 ~ 125°C 封装/外壳:24-WQFN 裸露焊盘 包装:带卷 (TR) |
| LTC1735CS#PBF | 功能描述:IC REG CTRLR BUCK PWM CM 16-SOIC RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 特色产品:LM3753/54 Scalable 2-Phase Synchronous Buck Controllers 标准包装:1 系列:PowerWise® PWM 型:电压模式 输出数:1 频率 - 最大:1MHz 占空比:81% 电源电压:4.5 V ~ 18 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:-5°C ~ 125°C 封装/外壳:32-WFQFN 裸露焊盘 包装:Digi-Reel® 产品目录页面:1303 (CN2011-ZH PDF) 其它名称:LM3754SQDKR |
| LTC1735CS#TR | 功能描述:IC REG CTRLR BUCK PWM CM 16-SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:500kHz 占空比:96% 电源电压:4 V ~ 36 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 ~ 125°C 封装/外壳:24-WQFN 裸露焊盘 包装:带卷 (TR) |
| LTC1735CS#TRPBF | 功能描述:IC REG CTRLR BUCK PWM CM 16-SOIC RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:500kHz 占空比:96% 电源电压:4 V ~ 36 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 ~ 125°C 封装/外壳:24-WQFN 裸露焊盘 包装:带卷 (TR) |
| LTC1735CS-1 | 功能描述:IC REG CTRLR BUCK PWM CM 16-SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 切换控制器 系列:- 标准包装:2,500 系列:- PWM 型:电流模式 输出数:1 频率 - 最大:500kHz 占空比:96% 电源电压:4 V ~ 36 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 ~ 125°C 封装/外壳:24-WQFN 裸露焊盘 包装:带卷 (TR) |
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