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参数资料
| 型号: | MDC3105LT1G |
| 厂商: | ON Semiconductor |
| 文件页数: | 8/14页 |
| 文件大小: | 0K |
| 描述: | IC RELAY/DRVR INDUCT LOAD SOT23 |
| 标准包装: | 1 |
| 类型: | 继电/负载驱动器 |
| 输入类型: | 非反相 |
| 输出数: | 1 |
| 电流 - 输出 / 通道: | 400mA |
| 电流 - 峰值输出: | 500mA |
| 电源电压: | 6V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | TO-236-3,SC-59,SOT-23-3 |
| 供应商设备封装: | SOT-23-3(TO-236) |
| 包装: | 标准包装 |
| 产品目录页面: | 1118 (CN2011-ZH PDF) |
| 其它名称: | MDC3105LT1GOSDKR |
��
�
�MDC3105�
�Using� TTR� Designing� for� Pulsed� Operation�
�For� a� repetitive� pulse� operating� condition,� time� averaging�
�allows� one� to� increase� a� device’s� peak� power� dissipation�
�rating� above� the� average� rating� by� dividing� by� the� duty� cycle�
�of� the� repetitive� pulse� train.� Thus,� a� continuous� rating� of� 200�
�mW� of� dissipation� is� increased� to� 1.0� W� peak� for� a� 20%� duty�
�cycle� pulse� train.� However,� this� only� holds� true� for� pulse�
�widths� which� are� short� compared� to� the� thermal� time�
�constant� of� the� semiconductor� device� to� which� they� are�
�applied.�
�For� pulse� widths� which� are� significant� compared� to� the�
�thermal� time� constant� of� the� device,� the� peak� operating�
�condition� begins� to� look� more� like� a� continuous� duty�
�operating� condition� over� the� time� duration� of� the� pulse.� In�
�these� cases,� the� peak� power� dissipation� rating� cannot� be�
�merely� time� averaged� by� dividing� the� continuous� power�
�rating� by� the� duty� cycle� of� the� pulse� train.� Instead,� the�
�average� power� rating� can� only� be� scaled� up� a� reduced�
�amount� in� accordance� with� the� device’s� transient� thermal�
�response,� so� that� the� device’s� max� junction� temperature� is�
�not� exceeded.�
�Figure� 12� of� the� MDC3105� data� sheet� plots� its� transient�
�thermal� resistance,� r(t)� as� a� function� of� pulse� width� in� ms� for�
�various� pulse� train� duty� cycles� as� well� as� for� a� single� pulse�
�and� illustrates� this� effect.� For� short� pulse� widths� near� the� left�
�side� of� the� chart,� r(t),� the� factor,� by� which� the� continuous�
�duty� thermal� resistance� is� multiplied� to� determine� how� much�
�the� peak� power� rating� can� be� increased� above� the� average�
�power� rating,� approaches� the� duty� cycle� of� the� pulse� train,�
�which� is� the� expected� value.� However,� as� the� pulse� width� is�
�increased,� that� factor� eventually� approaches� 1.0� for� all� duty�
�cycles� indicating� that� the� pulse� width� is� sufficiently� long� to�
�appear� as� a� continuous� duty� condition� to� this� device.� For� the�
�MDC3105LT1,� this� pulse� width� is� about� 100� seconds.� At�
�this� and� larger� pulse� widths,� the� peak� power� dissipation�
�capability� is� the� same� as� the� continuous� duty� power�
�capability.�
�To� use� Figure� 12� to� determine� the� peak� power� rating� for�
�a� specific� application,� enter� the� chart� with� the� worst� case�
�pulse� condition,� that� is� the� max� pulse� width� and� max� duty�
�Also� note� that� these� calculations� assume� a� rectangular�
�pulse� shape� for� which� the� rise� and� fall� times� are� insignificant�
�compared� to� the� pulse� width.� If� this� is� not� the� case� in� a�
�specific� application,� then� the� V� O� and� I� O� waveforms� should�
�be� multiplied� together� and� the� resulting� power� waveform�
�integrated� to� find� the� total� dissipation� across� the� device.� This�
�then� would� be� the� number� that� has� to� be� less� than� or� equal�
�to� the� Pd(pk)� calculated� above.� A� circuit� simulator� having� a�
�waveform� calculator� may� prove� very� useful� for� this� purpose.�
�Notes� on� SOA� and� Time� Constant� Limitations�
�Figure� 10� is� the� Safe� Operating� Area� (SOA)� for� the�
�MDC3105.� Device� instantaneous� operation� should� never� be�
�pushed� beyond� these� limits.� It� shows� the� SOA� for� the�
�Transistor� “ON”� condition� as� well� as� the� SOA� for� the� Zener�
�during� the� turn� ?� off� transient.� The� max� current� is� limited� by�
�the� Izpk� capability� of� the� Zener� as� well� as� the� transistor� in�
�addition� to� the� max� input� current� through� the� resistor.� It�
�should� not� be� exceeded� at� any� temperature.� The� BJT� power�
�dissipation� limits� are� shown� for� various� pulse� widths� and�
�duty� cycles� at� an� ambient� temperature� of� 25� °� C.� The� voltage�
�limit� is� the� max� V� CC� that� can� be� applied� to� the� device.� When�
�the� input� to� the� device� is� switched� off,� the� BJT� “ON”� current�
�is� instantaneously� dumped� into� the� Zener� diode� where� it�
�begins� its� exponential� decay.� The� Zener� clamp� voltage� is� a�
�function� of� that� BJT� current� level� as� can� be� seen� by� the�
�bowing� of� the� V� Z� versus� I� Z� curve� at� the� higher� currents.� In�
�addition� to� the� Zener’s� current� limit� impacting� this� device’s�
�500� mA� max� rating,� the� clamping� diode� also� has� a� peak�
�energy� limit� as� well.� This� energy� limit� was� measured� using�
�a� rectangular� pulse� and� then� translated� to� an� exponential�
�equivalent� using� the� 2:1� relationship� between� the� L/R� time�
�constant� of� an� exponential� pulse� and� the� pulse� width� of� a�
�rectangular� pulse� having� equal� energy� content.� These� L/R�
�time� constant� limits� in� ms� appear� along� the� V� Z� versus� I� Z�
�curve� for� the� various� values� of� I� Z� at� which� the� Pd� lines�
�intersect� the� V� CC� limit.� The� L/R� time� constant� for� a� given�
�load� should� not� exceed� these� limits� at� their� respective�
�currents.� Precise� L/R� limits� on� Zener� energy� at� intermediate�
�current� levels� can� be� obtained� from� Figure� 11.�
�cycle� and� determine� the� worst� case� r(t)� for� your� application.�
�Then� calculate� the� peak� power� dissipation� allowed� by� using�
�the� equation,�
�Pd(pk)� =� (T� Jmax� ?� T� Amax� )� ÷� (R� q� JA� *� r(t))�
�Pd(pk)� =� (150� °� C� ?� T� Amax� )� ÷� (556� °� C/W� *� r(t))�
�Thus� for� a� 20%� duty� cycle� and� a� PW� =� 40� ms,� Figure� 12�
�yields� r(t)� =� 0.3� and� when� entered� in� the� above� equation,� the�
�max� allowable� Pd(pk)� =� 390� mW� for� a� max� T� A� =� 85� °� C.�
�http://onsemi.com�
�8�
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