参数资料
| 型号: | LT1786FCS#TR |
| 厂商: | Linear Technology |
| 文件页数: | 16/20页 |
| 文件大小: | 0K |
| 描述: | IC REG SW CCFL SMBUS PROG 16SOIC |
| 标准包装: | 2,500 |
| 应用: | 转换器,CCFL |
| 输入电压: | 4.5 V ~ 30 V |
| 输出数: | 1 |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 16-SOIC |
| 包装: | 带卷 (TR) |
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�LT1786F�
�APPLICATIO� N� S� I� N� FOR� M� ATIO� N�
�lamp� current� programmer� circuit.� The� compensation� ca-�
�pacitor� on� the� CCFL� V� C� pin� provides� stable� loop� compen-�
�sation� and� an� averaging� function� to� the� rectified� sinusoidal�
�lamp� current.� Therefore,� input� programming� current� re-�
�lates� to� one-half� of� average� lamp� current.�
�The� transfer� function� between� lamp� current� and� input�
�programming� current� must� be� empirically� determined� and�
�is� dependent� on� the� particular� lamp/display� housing� com-�
�bination� used.� The� lamp� and� display� housing� are� a� distrib-�
�uted� loss� structure� due� to� parasitic� lamp-to-frame� capaci-�
�tance.� This� means� that� the� current� flowing� at� the� high-�
�voltage� side� of� the� lamp� is� higher� than� what� is� flowing� at�
�the� DIO� pin� side� of� the� lamp.� The� input� programming�
�current� is� set� to� control� lamp� current� at� the� high-voltage�
�side� of� the� lamp,� even� though� the� feedback� signal� is� the�
�lamp� current� at� the� bottom� of� the� lamp.� This� ensures� that�
�the� lamp� is� not� overdriven� which� can� degrade� the� lamp’s�
�operating� lifetime.� Therefore,� the� full� scale� current� of� the�
�DAC� does� not� necessarily� correspond� to� the� current�
�required� to� set� maximum� lamp� current.�
�Floating� Lamp� Configuration�
�In� a� floating� lamp� configuration,� the� lamp� is� fully� floating�
�with� no� galvanic� connection� to� ground.� This� allows� the�
�transformer� to� provide� symmetric� differential� drive� to� the�
�lamp.� Balanced� drive� eliminates� the� field� imbalance� asso-�
�ciated� with� parasitic� lamp-to-frame� capacitance� and� re-�
�duces� “thermometering”� (uneven� lamp� intensity� along� the�
�lamp� length)� at� low� lamp� currents.�
�Carefully� evaluate� display� designs� in� relation� to� the� physi-�
�cal� layout� of� the� lamp,� its� leads� and� the� construction� of� the�
�display� housing.� Parasitic� capacitance� from� any� high�
�voltage� point� to� DC� or� AC� ground� creates� paths� for�
�unwanted� current� flow.� This� parasitic� current� flow�
�degrades� electrical� efficiency� and� losses� up� to� 25%� have�
�been� observed� in� practice.� As� an� example,� at� a� Royer�
�operating� frequency� of� 60kHz,� 1pF� of� stray� capacitance�
�represents� an� impedance� of� 2.65M� ?� .� With� an� operating�
�lamp� voltage� of� 400V� and� an� operating� lamp� current� of�
�6mA,� the� parasitic� current� is� 150� μ� A.� This� additional� cur-�
�rent� must� be� supplied� by� the� transformer� secondary.�
�Layout� techniques� that� increase� parasitic� capacitance�
�include� long� high� voltage� lamp� leads,� reflective� metal� foil�
�16�
�around� the� lamp� and� displays� supplied� in� metal� enclo-�
�sures.� Losses� for� a� good� display� are� under� 5%,� whereas,�
�losses� for� a� bad� display� range� from� 5%� to� 25%.� Lossy�
�displays� are� the� primary� reason� to� use� a� floating� lamp�
�configuration.� Providing� symmetric,� differential� drive� to�
�the� lamp� reduces� the� total� parasitic� loss� by� one-half.�
�Maintaining� closed-loop� control� of� lamp� current� in� a�
�floating� lamp� configuration� necessitates� deriving� a� feed-�
�back� signal� from� the� primary� side� of� the� Royer� trans-�
�former.� Previous� solutions� have� used� an� external� preci-�
�sion� shunt� and� high-side� sense� amplifier� configuration.�
�This� approach� has� been� integrated� onto� the� LT1786F� for�
�simplicity� of� design� and� ease� of� use.� An� internal� 0.1� ?�
�resistor� monitors� the� Royer� converter� current� and� con-�
�nects� between� the� input� terminals� of� a� high-side� sense�
�amplifier.� A� 0� –� 1� Amp� Royer� primary-side,� center-tap�
�current� is� translated� to� a� 0� μ� A� to� 500� μ� A� sink� current� at� the�
�CCFL� V� C� pin� to� null� against� the� source� current� provided� by�
�the� lamp� current� programmer� circuit.� The� compensation�
�capacitor� on� the� CCFL� V� C� pin� provides� stable� loop� com-�
�pensation� and� an� averaging� function� to� the� error� sink�
�current.� Therefore,� input� programming� current� is� related�
�to� average� Royer� converter� current.� Floating� lamp� circuits�
�operate� similarly� to� grounded� lamp� circuits� except� for� the�
�derivation� of� the� feedback� signal.�
�The� transfer� function� between� lamp� current� and� input�
�programming� current� must� be� empirically� determined� and�
�is� dependent� upon� a� myriad� of� factors� including� lamp�
�characteristics,� display� construction,� transformer� turns�
�ratio� and� the� tuning� of� the� Royer� oscillator.� Once� again,�
�lamp� current� will� be� slightly� higher� at� one� end� of� the� lamp�
�and� input� programming� current� should� be� set� for� this�
�higher� level� to� ensure� that� the� lamp� is� not� overdriven.�
�The� internal� 0.1� ?� high-side� sense� resistor� on� the� LT1786F�
�is� rated� for� a� maximum� DC� current� of� 1A.� This� resistor� can�
�be� damaged� by� extremely� high� surge� currents� at� start-up.�
�The� Royer� converter� typically� uses� a� few� microfarads� of�
�bypass� capacitance� at� the� center� tap� of� the� transformer.�
�This� capacitor� charges� up� when� the� system� is� first� pow-�
�ered� by� the� battery� pack� or� an� AC� wall� adapter.� The� amount�
�of� current� delivered� at� start-up� can� be� very� large� if� the� total�
�impedance� in� this� path� is� small� and� the� voltage� source� has�
�high� current� capability.� Linear� Technology� recommends�
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相关代理商/技术参数 |
参数描述 |
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| LT1787 | 制造商:LINER 制造商全称:Linear Technology 功能描述:Precision, High Side Current Sense Amplifiers |
| LT1787_1 | 制造商:LINER 制造商全称:Linear Technology 功能描述:Precision, High Side Current Sense Amplifiers |
| LT1787CMS8 | 功能描述:IC AMP PREC CURRENT SENSE 8MSOP RoHS:否 类别:集成电路 (IC) >> Linear - Amplifiers - Instrumentation 系列:- 标准包装:50 系列:LinCMOS™ 放大器类型:通用 电路数:4 输出类型:- 转换速率:0.05 V/µs 增益带宽积:110kHz -3db带宽:- 电流 - 输入偏压:0.7pA 电压 - 输入偏移:210µV 电流 - 电源:57µA 电流 - 输出 / 通道:30mA 电压 - 电源,单路/双路(±):3 V ~ 16 V,±1.5 V ~ 8 V 工作温度:-40°C ~ 85°C 安装类型:表面贴装 封装/外壳:14-SOIC(0.154",3.90mm 宽) 供应商设备封装:14-SOIC 包装:管件 产品目录页面:865 (CN2011-ZH PDF) 其它名称:296-1834296-1834-5 |
| LT1787CMS8#PBF | 功能描述:IC AMP PREC CURRENT SENSE 8MSOP RoHS:是 类别:集成电路 (IC) >> Linear - Amplifiers - Instrumentation 系列:- 标准包装:50 系列:LinCMOS™ 放大器类型:通用 电路数:4 输出类型:- 转换速率:0.05 V/µs 增益带宽积:110kHz -3db带宽:- 电流 - 输入偏压:0.7pA 电压 - 输入偏移:210µV 电流 - 电源:57µA 电流 - 输出 / 通道:30mA 电压 - 电源,单路/双路(±):3 V ~ 16 V,±1.5 V ~ 8 V 工作温度:-40°C ~ 85°C 安装类型:表面贴装 封装/外壳:14-SOIC(0.154",3.90mm 宽) 供应商设备封装:14-SOIC 包装:管件 产品目录页面:865 (CN2011-ZH PDF) 其它名称:296-1834296-1834-5 |
| LT1787CMS8#TR | 功能描述:IC AMP PREC CURRENT SENSE 8MSOP RoHS:否 类别:集成电路 (IC) >> Linear - Amplifiers - Instrumentation 系列:- 标准包装:50 系列:LinCMOS™ 放大器类型:通用 电路数:4 输出类型:- 转换速率:0.05 V/µs 增益带宽积:110kHz -3db带宽:- 电流 - 输入偏压:0.7pA 电压 - 输入偏移:210µV 电流 - 电源:57µA 电流 - 输出 / 通道:30mA 电压 - 电源,单路/双路(±):3 V ~ 16 V,±1.5 V ~ 8 V 工作温度:-40°C ~ 85°C 安装类型:表面贴装 封装/外壳:14-SOIC(0.154",3.90mm 宽) 供应商设备封装:14-SOIC 包装:管件 产品目录页面:865 (CN2011-ZH PDF) 其它名称:296-1834296-1834-5 |
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