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�
�MC34151,� MC33151�
�the� NPN� pullup� during� the� negative� output� transient,� power�
�dissipation� at� high� frequencies� can� become� excessive.�
�Figures� 20,� 21,� and� 22� show� a� method� of� using� external�
�Schottky� diode� clamps� to� reduce� driver� power� dissipation.�
�Undervoltage� Lockout�
�An� undervoltage� lockout� with� hysteresis� prevents� erratic�
�system� operation� at� low� supply� voltages.� The� UVLO� forces�
�the� Drive� Outputs� into� a� low� state� as� V� CC� rises� from� 1.4� V�
�to� the� 5.8� V� upper� threshold.� The� lower� UVLO� threshold� is�
�5.3� V,� yielding� about� 500� mV� of� hysteresis.�
�gate� charge� information� on� their� data� sheets.� Figure� 18�
�shows� a� curve� of� gate� voltage� versus� gate� charge� for� the� ON�
�Semiconductor� MTM15N50.� Note� that� there� are� three�
�distinct� slopes� to� the� curve� representing� different� input�
�capacitance� values.� To� completely� switch� the� MOSFET�
�‘on’,� the� gate� must� be� brought� to� 10� V� with� respect� to� the�
�source.� The� graph� shows� that� a� gate� charge� Q� g� of� 110� nC� is�
�required� when� operating� the� MOSFET� with� a� drain� to� source�
�voltage� V� DS� of� 400� V.�
�16�
�Power� Dissipation�
�Circuit� performance� and� long� term� reliability� are�
�enhanced� with� reduced� die� temperature.� Die� temperature�
�increase� is� directly� related� to� the� power� that� the� integrated�
�12�
�MTM15N50�
�I� D� =� 15� A�
�T� A� =� 25� °� C�
�V� DS� = 100 V�
�V� DS� = 400 V�
�circuit� must� dissipate� and� the� total� thermal� resistance� from�
�the� junction� to� ambient.� The� formula� for� calculating� the�
�8.0�
�8.9 nF�
�junction� temperature� with� the� package� in� free� air� is:�
�T� J� =� T� A� +� P� D� (R� q� JA� )�
�where:� T� J� =� Junction� Temperature�
�T� A� =� Ambient� Temperature�
�P� D� =� Power� Dissipation�
�R� q� JA� =� Thermal� Resistance� Junction� to� Ambient�
�4.0�
�0�
�0�
�2.0 nF�
�40�
�80�
�Q� g� ,� GATE� CHARGE� (nC)�
�C� GS� =�
�120�
�D� Q� g�
�D� V� GS�
�160�
�There� are� three� basic� components� that� make� up� total�
�power� to� be� dissipated� when� driving� a� capacitive� load� with�
�respect� to� ground.� They� are:�
�P� D� =� P� Q� +� P� C� +� P� T�
�where:� P� Q� =� Quiescent� Power� Dissipation�
�P� C� =� Capacitive� Load� Power� Dissipation�
�P� T� =� Transition� Power� Dissipation�
�The� quiescent� power� supply� current� depends� on� the�
�supply� voltage� and� duty� cycle� as� shown� in� Figure� 17.� The�
�device’s� quiescent� power� dissipation� is:�
�P� Q� =� V� CC� I� CCL� (1� ?� D)� +� I� CCH� (D)�
�Figure� 18.� Gate� ?� To� ?� Source� Voltage�
�versus� Gate� Charge�
�The� capacitive� load� power� dissipation� is� directly� related� to�
�the� required� gate� charge,� and� operating� frequency.� The�
�capacitive� load� power� dissipation� per� driver� is:�
�P� C(MOSFET)� =� V� C� Q� g� f�
�The� flat� region� from� 10� nC� to� 55� nC� is� caused� by� the�
�drain� ?� to� ?� gate� Miller� capacitance,� occurring� while� the�
�MOSFET� is� in� the� linear� region� dissipating� substantial�
�amounts� of� power.� The� high� output� current� capability� of� the�
�where:�
�I� CCL� =� Supply� Current� with� Low� State� Drive�
�Outputs�
�I� CCH� =� Supply� Current� with� High� State� Drive�
�Outputs�
�D� =� Output� Duty� Cycle�
�MC34151� is� able� to� quickly� deliver� the� required� gate� charge�
�for� fast� power� efficient� MOSFET� switching.� By� operating�
�the� MC34151� at� a� higher� V� CC� ,� additional� charge� can� be�
�provided� to� bring� the� gate� above� 10� V.� This� will� reduce� the�
�‘on’� resistance� of� the� MOSFET� at� the� expense� of� higher�
�driver� dissipation� at� a� given� operating� frequency.�
�The� capacitive� load� power� dissipation� is� directly� related�
�to� the� load� capacitance� value,� frequency,� and� Drive� Output�
�voltage� swing.� The� capacitive� load� power� dissipation� per�
�driver� is:�
�The� transition� power� dissipation� is� due� to� extremely� short�
�simultaneous� conduction� of� internal� circuit� nodes� when� the�
�Drive� Outputs� change� state.� The� transition� power�
�dissipation� per� driver� is� approximately:�
�where:�
�P� C� =�
�V� OH� =�
�V� OL� =�
�C� L� =�
�f=�
�V� CC� (V� OH� ?� V� OL� )� C� L� f�
�High� State� Drive� Output� Voltage�
�Low� State� Drive� Output� Voltage�
�Load� Capacitance�
�frequency�
�P� T� =� V� CC� (1.08� V� CC� C� L� f� ?� 8� y� 10� ?� 4� )�
�P� T� must� be� greater� than� zero.�
�Switching� time� characterization� of� the� MC34151� is�
�performed� with� fixed� capacitive� loads.� Figure� 14� shows� that�
�for� small� capacitance� loads,� the� switching� speed� is� limited�
�When� driving� a� MOSFET,� the� calculation� of� capacitive�
�load� power� P� C� is� somewhat� complicated� by� the� changing�
�gate� to� source� capacitance� C� GS� as� the� device� switches.� To� aid�
�in� this� calculation,� power� MOSFET� manufacturers� provide�
�by� transistor� turn� ?� on/off� time� and� the� slew� rate� of� the�
�internal� nodes.� For� large� capacitance� loads,� the� switching�
�speed� is� limited� by� the� maximum� output� current� capability�
�of� the� integrated� circuit.�
�http://onsemi.com�
�7�
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