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| 型号: | LM2574N-005G |
| 厂商: | ON Semiconductor |
| 文件页数: | 16/26页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK 5V 0.5A 8DIP |
| 产品变化通告: | Product Obsolescence 19/Dec/2008 |
| 标准包装: | 50 |
| 类型: | 降压(降压) |
| 输出类型: | 固定 |
| 输出数: | 1 |
| 输出电压: | 5V |
| 输入电压: | 4.75 V ~ 40 V |
| PWM 型: | 电压模式 |
| 频率 - 开关: | 52kHz |
| 电流 - 输出: | 500mA |
| 同步整流器: | 无 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 通孔 |
| 封装/外壳: | 8-DIP(0.300",7.62mm) |
| 包装: | 管件 |
| 供应商设备封装: | 8-PDIP |
| 其它名称: | LM2574N-005G-ND LM2574N-005GOS |
��
�
�LM2574,� NCV2574�
�Inductor�
�The� magnetic� components� are� the� cornerstone� of� all�
�switching� power� supply� designs.� The� style� of� the� core� and�
�the� winding� technique� used� in� the� magnetic� component’s�
�design� have� a� great� influence� on� the� reliability� of� the� overall�
�power� supply.�
�Using� an� improper� or� poorly� designed� inductor� can� cause�
�high� voltage� spikes� generated� by� the� rate� of� transitions� in�
�current� within� the� switching� power� supply,� and� the�
�possibility� of� core� saturation� can� arise� during� an� abnormal�
�operational� mode.� Voltage� spikes� can� cause� the�
�semiconductors� to� enter� avalanche� breakdown� and� the� part�
�can� instantly� fail� if� enough� energy� is� applied.� It� can� also�
�cause� significant� RFI� (Radio� Frequency� Interference)� and�
�EMI� (Electro?Magnetic� Interference)� problems.�
�Continuous� and� Discontinuous� Mode� of� Operation�
�The� LM2574� step?down� converter� can� operate� in� both� the�
�continuous� and� the� discontinuous� modes� of� operation.� The�
�regulator� works� in� the� continuous� mode� when� loads� are�
�relatively� heavy,� the� current� flows� through� the� inductor�
�continuously� and� never� falls� to� zero.� Under� light� load�
�conditions,� the� circuit� will� be� forced� to� the� discontinuous�
�mode� when� inductor� current� falls� to� zero� for� certain� period�
�of� time� (see� Figure� 24� and� Figure� 25).� Each� mode� has�
�distinctively� different� operating� characteristics,� which� can�
�affect� the� regulator� performance� and� requirements.� In� many�
�cases� the� preferred� mode� of� operation� is� the� continuous�
�mode.� It� offers� greater� output� power,� lower� peak� currents� in�
�the� switch,� inductor� and� diode,� and� can� have� a� lower� output�
�ripple� voltage.� On� the� other� hand� it� does� require� larger�
�inductor� values� to� keep� the� inductor� current� flowing�
�continuously,� especially� at� low� output� load� currents� and/or�
�high� input� voltages.�
�To� simplify� the� inductor� selection� process,� an� inductor�
�selection� guide� for� the� LM2574� regulator� was� added� to� this�
�data� sheet� (Figures� 19� through� 23).� This� guide� assumes� that�
�the� regulator� is� operating� in� the� continuous� mode,� and�
�selects� an� inductor� that� will� allow� a� peak?to?peak� inductor�
�ripple� current� to� be� a� certain� percentage� of� the� maximum�
�design� load� current.� This� percentage� is� allowed� to� change� as�
�different� design� load� currents� are� selected.� For� light� loads�
�(less� than� approximately� 0.2� A)� it� may� be� desirable� to�
�operate� the� regulator� in� the� discontinuous� mode,� because� the�
�inductor� value� and� size� can� be� kept� relatively� low.�
�Consequently,� the� percentage� of� inductor� peak?to?peak�
�current� increases.� This� discontinuous� mode� of� operation� is�
�perfectly� acceptable� for� this� type� of� switching� converter.�
�Any� buck� regulator� will� be� forced� to� enter� discontinuous�
�mode� if� the� load� current� is� light� enough.�
�Selecting� the� Right� Inductor� Style�
�Some� important� considerations� when� selecting� a� core� type�
�are� core� material,� cost,� the� output� power� of� the� power� supply,�
�the� physical� volume� the� inductor� must� fit� within,� and� the�
�amount� of� EMI� (Electro?Magnetic� Interference)� shielding�
�that� the� core� must� provide.� There� are� many� different� styles�
�of� inductors� available,� such� as� pot� core,� E?core,� toroid� and�
�bobbin� core,� as� well� as� different� core� materials� such� as�
�ferrites� and� powdered� iron� from� different� manufacturers.�
�For� high� quality� design� regulators� the� toroid� core� seems� to�
�be� the� best� choice.� Since� the� magnetic� flux� is� contained�
�within� the� core,� it� generates� less� EMI,� reducing� noise�
�problems� in� sensitive� circuits.� The� least� expensive� is� the�
�bobbin� core� type,� which� consists� of� wire� wound� on� a� ferrite�
�rod� core.� This� type� of� inductor� generates� more� EMI� due� to�
�the� fact� that� its� core� is� open,� and� the� magnetic� flux� is� not�
�contained� within� the� core.�
�When� multiple� switching� regulators� are� located� on� the�
�same� printed� circuit� board,� open� core� magnetics� can� cause�
�interference� between� two� or� more� of� the� regulator� circuits,�
�especially� at� high� currents� due� to� mutual� coupling.� A� toroid,�
�pot� core� or� E?core� (closed� magnetic� structure)� should� be�
�used� in� such� applications.�
�Do� Not� Operate� an� Inductor� Beyond� its� Maximum�
�Rated� Current�
�Exceeding� an� inductor� ’s� maximum� current� rating� may�
�cause� the� inductor� to� overheat� because� of� the� copper� wire�
�losses,� or� the� core� may� saturate.� Core� saturation� occurs� when�
�the� flux� density� is� too� high� and� consequently� the� cross�
�sectional� area� of� the� core� can� no� longer� support� additional�
�lines� of� magnetic� flux.�
�This� causes� the� permeability� of� the� core� to� drop,� the�
�inductance� value� decreases� rapidly� and� the� inductor� begins�
�to� look� mainly� resistive.� It� has� only� the� dc� resistance� of� the�
�winding.� This� can� cause� the� switch� current� to� rise� very�
�rapidly� and� force� the� LM2574� internal� switch� into�
�cycle?by?cycle� current� limit,� thus� reducing� the� dc� output�
�load� current.� This� can� also� result� in� overheating� of� the�
�inductor� and/or� the� LM2574.� Different� inductor� types� have�
�different� saturation� characteristics,� and� this� should� be� kept�
�in� mind� when� selecting� an� inductor.�
�http://onsemi.com�
�16�
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| LM2574N-012 | 功能描述:直流/直流开关调节器 12V 500mA Buck PWM RoHS:否 制造商:International Rectifier 最大输入电压:21 V 开关频率:1.5 MHz 输出电压:0.5 V to 0.86 V 输出电流:4 A 输出端数量: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:PQFN 4 x 5 |
| LM2574N-012G | 功能描述:直流/直流开关转换器 12V 500mA Buck PWM RoHS:否 制造商:STMicroelectronics 最大输入电压:4.5 V 开关频率:1.5 MHz 输出电压:4.6 V 输出电流:250 mA 输出端数量:2 最大工作温度:+ 85 C 安装风格:SMD/SMT |
| LM2574N-015 | 功能描述:直流/直流开关调节器 15V 500mA Buck PWM RoHS:否 制造商:International Rectifier 最大输入电压:21 V 开关频率:1.5 MHz 输出电压:0.5 V to 0.86 V 输出电流:4 A 输出端数量: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:PQFN 4 x 5 |
| LM2574N-015G | 功能描述:直流/直流开关调节器 15V 500mA Buck PWM RoHS:否 制造商:International Rectifier 最大输入电压:21 V 开关频率:1.5 MHz 输出电压:0.5 V to 0.86 V 输出电流:4 A 输出端数量: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:PQFN 4 x 5 |
| LM2574N-12 | 功能描述:直流/直流开关转换器 RoHS:否 制造商:STMicroelectronics 最大输入电压:4.5 V 开关频率:1.5 MHz 输出电压:4.6 V 输出电流:250 mA 输出端数量:2 最大工作温度:+ 85 C 安装风格:SMD/SMT |
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