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参数资料
| 型号: | MAX8795AETJ+C7P |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 24/31页 |
| 文件大小: | 0K |
| 描述: | IC TFT-LCD DC/DC CONV 32-TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 60 |
| 应用: | 转换器,TFT,LCD |
| 输入电压: | 2.5 V ~ 6 V |
| 输出数: | 8 |
| 输出电压: | 2.5 V ~ 18 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-WFQFN 裸露焊盘 |
| 供应商设备封装: | 32-TQFN-EP(5x5) |
| 包装: | 管件 |
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��
�
�TFT-LCD� DC-DC� Converter� with�
�Operational� Amplifiers�
�and� gate-off� linear-regulator� controllers� are� 0.1mA.�
�Therefore,� the� base-to-emitter� resistor� for� both� linear�
�regulators� should� be� chosen� to� set� 0.1mA� bias� current:�
�4)� Next,� calculate� the� pole� set� by� the� linear� regulator’s�
�feedback� resistance� and� the� capacitance� between�
�FB_� and� AGND� (including� stray� capacitance):�
�R� BE� =�
�=� ≈� 6� .� 8� k� ?�
�V� BE� 0� .� 7� V�
�0� .� 1� mA� 0� .� 1� mA�
�The� output� capacitor� and� the� load� resistance� create� the�
�f� POLE� _� FB� =�
�1�
�2� π� ×� C� FB� ×� (� R� UPPER� ||� R� LOWER� )�
�f� POLE� _� LR� =�
�f� POLE� _� ESR� =�
�dominant pole in the system. However, the internal�
�amplifier� delay,� pass� transistor’s� input� capacitance,�
�and� the� stray� capacitance� at� the� feedback� node� create�
�additional� poles� in� the� system,� and� the� output� capaci-�
�tor’s� ESR� generates� a� zero.� For� proper� operation,� use�
�the� following� equations� to� verify� the� linear� regulator� is�
�properly� compensated:�
�1)� First,� determine� the� dominant� pole� set� by� the� linear�
�regulator’s� output� capacitor� and� the� load� resistor:�
�I� LOAD� (� MAX� )_� LR�
�2� π� ×� C� OUT� _� LR� ×� V� OUT� _� LR�
�The� unity-gain� crossover� of� the� linear� regulator� is:�
�f� CROSSOVER� =� A� V_LR� � f� POLE_LR�
�2)� The� pole� created� by� the� internal� amplifier� delay� is�
�approximately� 1MHz:�
�f� POLE_AMP� =� 1MHz�
�3)� Next,� calculate� the� pole� set� by� the� transistor’s� input�
�capacitance,� the� transistor’s� input� resistance,� and�
�the� base-to-emitter� pullup� resistor:�
�where� CFB� is� the� capacitance� between� FB_� and�
�AGND,� R� UPPER� is� the� upper� resistor� of� the� linear� regu-�
�lator’s� feedback� divider,� and� R� LOWER� is� the� lower� resis-�
�tor� of� the� divider.�
�5)� Next,� calculate� the� zero� caused� by� the� output�
�capacitor’s� ESR:�
�1�
�2� π� ×� C� OUT� _� LR� ×� R� ESR�
�where� RESR� is� the� equivalent� series� resistance� of�
�COUT_LR.�
�To� ensure� stability,� choose� C� OUT_LR� large� enough� so�
�the� crossover� occurs� well� before� the� poles� and� zero�
�calculated� in� steps� 2� to� 5.� The� poles� in� steps� 3� and� 4�
�generally� occur� at� several� megahertz,� and� using�
�ceramic� capacitors� ensures� the� ESR� zero� occurs� at�
�several� megahertz� as� well.� Placing� the� crossover� below�
�500kHz� is� sufficient� to� avoid� the� amplifier-delay� pole�
�and� generally� works� well,� unless� unusual� component�
�choices� or� extra� capacitances� move� one� of� the� other�
�f� POLE� _� IN� =�
�1�
�2� π� ×� C� IN� ×� (� R� BE� ||� R� IN� )�
�poles� or� the� zero� below� 1MHz.�
�Applications� Information�
�C� IN� =�
�,� R� IN� =�
�where� :�
�g� m� h� FE�
�2� π� f� T� g� m�
�g� m� is� the� transconductance� of� the� pass� transistor,� and� f� T�
�is� the� transition� frequency.� Both� parameters� can� be� found�
�in� the� transistor’s� data� sheet.� Because� RBE� is� much�
�greater� than� RIN,� the� above� equation� can� be� simplified:�
�Power� Dissipation�
�An� IC’s� maximum� power� dissipation� depends� on� the�
�thermal� resistance� from� the� die� to� the� ambient� environ-�
�ment� and� the� ambient� temperature.� The� thermal� resis-�
�tance� depends� on� the� IC� package,� PCB� copper� area,�
�other� thermal� mass,� and� airflow.�
�The� MAX8795A,� with� its� exposed� backside� paddle� sol-�
�dered� to� 1in� 2� of� PCB� copper� and� a� large� internal� ground�
�f� POLE� _� IN� =�
�1�
�2� π� ×� C� IN� ×� R� IN�
�plane� layer,� can� dissipate� approximately� 2.76W� into�
�+70� °� C� still� air.� More� PCB� copper,� cooler� ambient� air,�
�and� more� airflow� increase� the� possible� dissipation,� while�
�f� POLE� _� IN� =� T�
�Substituting for CIN and RIN yields:�
�f�
�h� FE�
�less� copper� or� warmer� air� decreases� the� IC’s� dissipation�
�capability.� The� major� components� of� power� dissipation�
�are� the� power� dissipated� in� the� step-up� regulator� and�
�the� power� dissipated� by� the� operational� amplifiers.�
�24�
�______________________________________________________________________________________�
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