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参数资料
| 型号: | ADP2105ACPZ-1.2-R7 |
| 厂商: | Analog Devices Inc |
| 文件页数: | 22/36页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK SYNC 1.2V 1A 16LFCSP |
| 产品培训模块: | Powering 90nm/65nm FPGAs and Processors |
| 设计资源: | Powering the AD9788 Using ADP2105 for Increased Efficiency (CN0141) |
| 标准包装: | 1 |
| 类型: | 降压(降压) |
| 输出类型: | 固定 |
| 输出数: | 1 |
| 输出电压: | 1.2V |
| 输入电压: | 2.7 V ~ 5.5 V |
| PWM 型: | 电流模式 |
| 频率 - 开关: | 1.2MHz |
| 电流 - 输出: | 1A |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-VQFN 裸露焊盘,CSP |
| 包装: | 标准包装 |
| 供应商设备封装: | 16-LFCSP-VQ |
| 其它名称: | ADP2105ACPZ-1.2-R7DKR |
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��
�
�P� TRAN� =�
�� I� OUT� � (� t� ON� +� t� OFF� )� � f� SW�
�ADP2105/ADP2106/ADP2107�
�EFFICIENCY� CONSIDERATIONS�
�Efficiency� is� the� ratio� of� output� power� to� input� power.� The� high�
�efficiency� of� the� ADP2105/ADP2106/ADP2107� has� two� distinct�
�advantages.� First,� only� a� small� amount� of� power� is� lost� in� the� dc-�
�to-dc� converter� package� that� reduces� thermal� constraints.� Second,�
�the� high� efficiency� delivers� the� maximum� output� power� for� the�
�given� input� power,� extending� battery� life� in� portable� applications.�
�There� are� four� major� sources� of� power� loss� in� dc-to-dc�
�converters� like� the� ADP2105/ADP2106/ADP2107:�
�?� Power� switch� conduction� losses�
�?� Inductor� losses�
�?� Switching� losses�
�?� Transition� losses�
�Power� Switch� Conduction� Losses�
�Power� switch� conduction� losses� are� caused� by� the� flow� of� output�
�current� through� the� P-channel� power� switch� and� the� N-channel�
�synchronous� rectifier,� which� have� internal� resistances� (� R� DS(ON)� )�
�associated� with� them.� The� amount� of� power� loss� can� be� approxi-�
�mated� by�
�P� SW� ?� COND� =� [� R� DS(ON)� ?� P� � D� +� R� DS(ON)� ?� N� � (1� ?� D� )]� � I� OUT2�
�where� D� =� V� OUT� /V� IN� .�
�The� internal� resistance� of� the� power� switches� increases� with�
��and� Figure� 21� show� the� change� in� R� DS(ON)� vs.� input� voltage,�
�whereas� Figure� 29� and� Figure� 30� show� the� change� in� R� DS(ON)� vs.�
�temperature� for� both� power� devices.�
�Inductor� Losses�
�Inductor� conduction� losses� are� caused� by� the� flow� of� current�
�through� the� inductor,� which� has� an� internal� resistance� (DCR)�
�associated� with� it.� Larger� sized� inductors� have� smaller� DCR,�
�which� can� improve� inductor� conduction� losses.�
�Inductor� core� losses� are� related� to� the� magnetic� permeability� of�
�the� core� material.� Because� the� ADP2105/ADP2106/ADP2107�
�are� high� switching� frequency� dc-to-dc� converters,� shielded� ferrite�
�core� material� is� recommended� for� its� low� core� losses� and� low� EMI.�
�The� total� amount� of� inductor� power� loss� can� be� calculated� by�
�P� L� =� DCR� � I� OUT2� +� Core� Losses�
�Switching� Losses�
�Switching� losses� are� associated� with� the� current� drawn� by� the�
�driver� to� turn� on� and� turn� off� the� power� devices� at� the�
�switching� frequency.� Each� time� a� power� device� gate� is� turned� on�
�and� turned� off,� the� driver� transfers� a� charge� ΔQ� from� the� input�
�supply� to� the� gate� and� then� from� the� gate� to� ground.�
�The� amount� of� power� loss� can� by� calculated� by�
�P� SW� =� (� C� GATE� ?� P� +� C� GATE� ?� N� )� � V� IN2� � f� SW�
�Data� Sheet�
�Transition� Losses�
�Transition� losses� occur� because� the� P-channel� MOSFET� power�
�switch� cannot� turn� on� or� turn� off� instantaneously.� At� the� middle� of�
�an� LX� (switch)� node� transition,� the� power� switch� is� providing� all�
�the� inductor� current,� while� the� source� to� drain� voltage� of� the�
�power� switch� is� half� the� input� voltage,� resulting� in� power� loss.�
�Transition� losses� increase� with� load� current� and� input� voltage�
�and� occur� twice� for� each� switching� cycle.�
�The� amount� of� power� loss� can� be� calculated� by�
�V� IN�
�2�
�where� t� ON� and� t� OFF� are� the� rise� time� and� fall� time� of� the� LX�
�(switch)� node,� and� are� both� approximately� 3� ns.�
�THERMAL� CONSIDERATIONS�
�In� most� applications,� the� ADP2105/ADP2106/ADP2107� do� not�
�dissipate� a� lot� of� heat� due� to� their� high� efficiency.� However,� in�
�applications� with� high� ambient� temperature,� low� supply� voltage,�
�and� high� duty� cycle,� the� heat� dissipated� in� the� package� is� large�
�enough� that� it� can� cause� the� junction� temperature� of� the� die� to�
�exceed� the� maximum� junction� temperature� of� 125°C.� Once� the�
�junction� temperature� exceeds� 140°C,� the� converter� goes� into�
�thermal� shutdown.� To� prevent� any� permanent� damage� it� recovers�
�only� after� the� junction� temperature� has� decreased� below� 100°C.�
�Therefore,� thermal� analysis� for� the� chosen� application� solution�
�is� very� important� to� guarantee� reliable� performance� over� all�
�conditions.�
�The� junction� temperature� of� the� die� is� the� sum� of� the� ambient�
�temperature� of� the� environment� and� the� temperature� rise� of� the�
�package� due� to� the� power� dissipation,� as� shown� in� the� following�
�equation:�
�T� J� =� T� A� +� T� R�
�where:�
�T� J� is� the� junction� temperature.�
�T� A� is� the� ambient� temperature.�
�T� R� is� the� rise� in� temperature� of� the� package� due� to� the� power�
�dissipation� in� the� package.�
�The� rise� in� temperature� of� the� package� is� directly� proportional�
�to� the� power� dissipation� in� the� package.� The� proportionality�
�constant� for� this� relationship� is� defined� as� the� thermal� resistance�
�from� the� junction� of� the� die� to� the� ambient� temperature,� as�
�shown� in� the� following� equation:�
�T� R� =� θ� JA� ×� P� D�
�where:�
�T� R� is� the� rise� in� temperature� of� the� package.�
�P� D� is� the� power� dissipation� in� the� package.�
�θ� JA� is� the� thermal� resistance� from� the� junction� of� the� die� to� the�
�ambient� temperature� of� the� package.�
�where:�
�(� C� GATE� ?� P� +� C� GATE� ?� N� )� ≈� 600� pF.�
�f� SW� =� 1.2� MHz,� the� switching� frequency.�
�Rev.� D� |� Page� 22� of� 36�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| ADP2105ACPZ-3.3 | 制造商:Analog Devices 功能描述:V REG 1A 3.3V SMD LFCSP-16 2105 |
| ADP2105ACPZ-3.3R7 | 制造商:Rochester Electronics LLC 功能描述: 制造商:Analog Devices 功能描述: |
| ADP2105ACPZ-3.3-R7 | 功能描述:IC REG BUCK SYNC 3.3V 1A 16LFCSP RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 开关稳压器 系列:- 标准包装:500 系列:- 类型:切换式电容器(充电泵),反相 输出类型:固定 输出数:1 输出电压:-3V 输入电压:2.3 V ~ 5.5 V PWM 型:Burst Mode? 频率 - 开关:900kHz 电流 - 输出:100mA 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 细型,TSOT-23-6 包装:带卷 (TR) 供应商设备封装:TSOT-23-6 其它名称:LTC1983ES6-3#TRMTR |
| ADP2105ACPZ-R7 | 功能描述:IC REG BUCK SYNC ADJ 1A 16LFCSP RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - DC DC 开关稳压器 系列:- 标准包装:500 系列:- 类型:切换式电容器(充电泵),反相 输出类型:固定 输出数:1 输出电压:-3V 输入电压:2.3 V ~ 5.5 V PWM 型:Burst Mode? 频率 - 开关:900kHz 电流 - 输出:100mA 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 细型,TSOT-23-6 包装:带卷 (TR) 供应商设备封装:TSOT-23-6 其它名称:LTC1983ES6-3#TRMTR |
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