参数资料
| 型号: | LT3020IMS8#PBF |
| 厂商: | Linear Technology |
| 文件页数: | 13/16页 |
| 文件大小: | 0K |
| 描述: | IC REG LDO ADJ .1A 8MSOP |
| 标准包装: | 50 |
| 稳压器拓扑结构: | 正,可调式 |
| 输出电压: | 0.2 V ~ 9.5 V |
| 输入电压: | 0.9 V ~ 10 V |
| 电压 - 压降(标准): | 0.15V @ 100mA |
| 稳压器数量: | 1 |
| 电流 - 输出: | 100mA |
| 电流 - 限制(最小): | 110mA |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-TSSOP,8-MSOP(0.118",3.00mm 宽) |
| 供应商设备封装: | 8-MSOP |
| 包装: | 管件 |
��
�
�LT3020/LT3020-1.2/�
�LT3020-1.5/LT3020-1.8�
�APPLICATIO� S� I� FOR� ATIO�
�and� the� output� voltage� clamps� at� a� Schottky� diode� above�
�ground.� Please� note� that� the� behavior� described� above�
�applies� to� the� LT3020� only.� If� a� resistor� divider� is� con-�
�nected� under� the� same� conditions,� there� will� be� additional�
�V/R� current.�
�In� circuits� where� a� backup� battery� is� required,� several�
�different� input/output� conditions� can� occur.� The� output�
�voltage� may� be� held� up� while� the� input� is� either� pulled� to�
�ground,� pulled� to� some� intermediate� voltage� or� is� left� open�
�circuit.� In� the� case� where� the� input� is� grounded,� there� is�
�less� than� 1� μ� A� of� reverse� output� current.�
�If� the� LT3020� IN� pin� is� forced� below� the� OUT� pin� or� the� OUT�
�pin� is� pulled� above� the� IN� pin,� input� current� drops� to� less�
�than� 10� μ� A� typically.� This� occurs� if� the� LT3020� input� is�
�connected� to� a� discharged� (low� voltage)� battery� and� either�
�a� backup� battery� or� a� second� regulator� circuit� holds� up� the�
�output.� The� state� of� the� SHDN� pin� has� no� effect� on� the�
�reverse� output� current� if� OUT� is� pulled� above� IN.�
�Input� Capacitance� and� Stability�
�The� LT3020� is� designed� to� be� stable� with� a� minimum�
�capacitance� of� 2.2� μ� F� placed� at� the� IN� pin.� Ceramic� capaci-�
�tors� with� very� low� ESR� may� be� used.� However,� in� cases�
�where� a� long� wire� is� used� to� connect� a� power� supply� to� the�
�input� of� the� LT3020� (and� also� from� the� ground� of� the�
�LT3020� back� to� the� power� supply� ground),� use� of� low�
�value� input� capacitors� combined� with� an� output� load�
�current� of� 20mA� or� greater� may� result� in� an� unstable�
�application.� This� is� due� to� the� inductance� of� the� wire�
�forming� an� LC� tank� circuit� with� the� input� capacitor� and� not�
�a� result� of� the� LT3020� being� unstable.�
�The� self-inductance,� or� isolated� inductance,� of� a� wire� is�
�of� a� wire� does� not� have� a� major� influence� on� its� self-�
�inductance.� For� example,� the� self� inductance� of� a� 2-AWG�
�isolated� wire� with� a� diameter� of� 0.26� in.� is� about� half� the�
�inductance� of� a� 30-AWG� wire� with� a� diameter� of� 0.01� in.�
�One� foot� of� 30-AWG� wire� has� 465nH� of� self� inductance.�
�The� overall� self-inductance� of� a� wire� can� be� reduced� in� two�
�ways.� One� is� to� divide� the� current� flowing� towards� the�
�LT3020� between� two� parallel� conductors.� In� this� case,� the�
�farther� the� wires� are� placed� apart� from� each� other,� the�
�more� inductance� will� be� reduced,� up� to� a� 50%� reduction�
�when� placed� a� few� inches� apart.� Splitting� the� wires� basi-�
�cally� connects� two� equal� inductors� in� parallel.� However,�
�when� placed� in� close� proximity� from� each� other,� mutual�
�inductance� is� added� to� the� overall� self� inductance� of� the�
�wires.� The� most� effective� way� to� reduce� overall� inductance�
�is� to� place� the� forward� and� return-current� conductors� (the�
�wire� for� the� input� and� the� wire� for� ground)� in� very� close�
�proximity.� Two� 30-AWG� wires� separated� by� 0.02� in.� re-�
�duce� the� overall� self-inductance� to� about� one-fifth� of� a�
�single� isolated� wire.�
�If� the� LT3020� is� powered� by� a� battery� mounted� in� close�
�proximity� on� the� same� circuit� board,� a� 2.2� μ� F� input� capaci-�
�tor� is� sufficient� for� stability.� However,� if� the� LT3020� is�
�powered� by� a� distant� supply,� use� a� larger� value� input�
�capacitor� following� the� guideline� of� roughly� 1� μ� F� (in� addi-�
�tion� to� the� 2.2� μ� F� minimum)� per� 8� inches� of� wire� length.� As�
�power� supply� output� impedance� may� vary,� the� minimum�
�input� capacitance� needed� to� stabilize� the� application� may�
�also� vary.� Extra� capacitance� may� also� be� placed� directly� on�
�the� output� of� the� power� supply;� however,� this� will� require�
�an� order� of� magnitude� more� capacitance� as� opposed� to�
�placing� extra� capacitance� in� close� proximity� to� the� LT3020.�
�Furthermore,� series� resistance� may� be� placed� between� the�
�supply� and� the� input� of� the� LT3020� to� stabilize� the� appli-�
�cation;� as� little� as� 0.1� ?� to� 0.5� ?� will� suffice.�
�directly� proportional� to� its� length.� However,� the� diameter�
�3020fc�
�13�
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