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�MTB2P50E�
�POWER� MOSFET� SWITCHING�
�Switching� behavior� is� most� easily� modeled� and� predicted�
�by� recognizing� that� the� power� MOSFET� is� charge�
�controlled.� The� lengths� of� various� switching� intervals� (� D� t)�
�are� determined� by� how� fast� the� FET� input� capacitance� can�
�be� charged� by� current� from� the� generator.�
�The� published� capacitance� data� is� difficult� to� use� for�
�calculating� rise� and� fall� because� drain?gate� capacitance�
�varies� greatly� with� applied� voltage.� Accordingly,� gate�
�charge� data� is� used.� In� most� cases,� a� satisfactory� estimate� of�
�average� input� current� (I� G(AV)� )� can� be� made� from� a�
�rudimentary� analysis� of� the� drive� circuit� so� that�
�t� =� Q/I� G(AV)�
�During� the� rise� and� fall� time� interval� when� switching� a�
�resistive� load,� V� GS� remains� virtually� constant� at� a� level�
�known� as� the� plateau� voltage,� V� SGP� .� Therefore,� rise� and� fall�
�times� may� be� approximated� by� the� following:�
�t� r� =� Q� 2� x� R� G� /(V� GG� ?� V� GSP� )�
�t� f� =� Q� 2� x� R� G� /V� GSP�
�where�
�V� GG� =� the� gate� drive� voltage,� which� varies� from� zero� to� V� GG�
�R� G� =� the� gate� drive� resistance�
�and� Q� 2� and� V� GSP� are� read� from� the� gate� charge� curve.�
�During� the� turn?on� and� turn?off� delay� times,� gate� current� is�
�not� constant.� The� simplest� calculation� uses� appropriate�
�values� from� the� capacitance� curves� in� a� standard� equation� for�
�voltage� change� in� an� RC� network.� The� equations� are:�
�t� d(on)� =� R� G� C� iss� In� [V� GG� /(V� GG� ?� V� GSP� )]�
�t� d(off)� =� R� G� C� iss� In� (V� GG� /V� GSP� )�
�The� capacitance� (C� iss� )� is� read� from� the� capacitance� curve� at�
�a� voltage� corresponding� to� the� off?state� condition� when�
�calculating� t� d(on)� and� is� read� at� a� voltage� corresponding� to� the�
�on?state� when� calculating� t� d(off)� .�
�At� high� switching� speeds,� parasitic� circuit� elements�
�complicate� the� analysis.� The� inductance� of� the� MOSFET�
�source� lead,� inside� the� package� and� in� the� circuit� wiring� which�
�is� common� to� both� the� drain� and� gate� current� paths,� produces�
�a� voltage� at� the� source� which� reduces� the� gate� drive� current.�
�The� voltage� is� determined� by� Ldi/dt,� but� since� di/dt� is� a�
�function� of� drain� current,� the� mathematical� solution� is�
�complex.� The� MOSFET� output� capacitance� also� complicates�
�the� mathematics.� And� finally,� MOSFETs� have� finite� internal�
�gate� resistance� which� effectively� adds� to� the� resistance� of� the�
�driving� source,� but� the� internal� resistance� is� difficult� to�
�measure� and,� consequently,� is� not� specified.�
�The� resistive� switching� time� variation� versus� gate�
�resistance� (Figure� 9)� shows� how� typical� switching�
�performance� is� affected� by� the� parasitic� circuit� elements.� If�
�the� parasitics� were� not� present,� the� slope� of� the� curves� would�
�maintain� a� value� of� unity� regardless� of� the� switching� speed.�
�The� circuit� used� to� obtain� the� data� is� constructed� to� minimize�
�common� inductance� in� the� drain� and� gate� circuit� loops� and�
�is� believed� readily� achievable� with� board� mounted�
�components.� Most� power� electronic� loads� are� inductive;� the�
�data� in� the� figure� is� taken� with� a� resistive� load,� which�
�approximates� an� optimally� snubbed� inductive� load.� Power�
�MOSFETs� may� be� safely� operated� into� an� inductive� load;�
�however,� snubbing� reduces� switching� losses.�
�1800�
�1600�
�1400�
�V� DS� =� 0� V�
�C� iss�
�V� GS� =� 0� V�
�T� J� =� 25� °� C�
�1000�
�V� GS� =� 0� V�
�T� J� =� 25� °� C�
�C� iss�
�1200�
�100�
�1000�
�800�
�C� iss�
�C� oss�
�600�
�C� rss�
�10�
�C� rss�
�400�
�200�
�C� rss�
�C� oss�
�0�
�10�
�5�
�0�
�5�
�10�
�15�
�20�
�25�
�1�
�10�
�100�
�1000�
�V� GS�
�V� DS�
�V� DS� ,� DRAIN?TO?SOURCE� VOLTAGE� (VOLTS)�
�GATE?TO?SOURCE� OR� DRAIN?TO?SOURCE� VOLTAGE� (VOLTS)�
�Figure� 7a.� Capacitance� Variation�
�http://onsemi.com�
�4�
�Figure� 7b.� High� Voltage� Capacitance�
�Variation�
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