a Explanation: Vo = √2Vs (1+cosα)/π.
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C.150000
C.150000
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A.Rising
A.Rising
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c Explanation: Form factor = RMS/Average vaules of current Therefore, FF = 2 I TAV = 35/2 = 17.5.
c
Explanation: Form factor = RMS/Average vaules of current
Therefore, FF = 2
I
TAV = 35/2 = 17.5.
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c Explanation: Vg.Ig = 0.5 W, the power dissipation mustn’t exceed the average power dissipation.
c
Explanation: Vg.Ig = 0.5 W, the power dissipation mustn’t exceed the average power
dissipation.
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d Explanation: As the gate characteristics is a plot of Ig vs Vg consisting of two curves one for the maximum values & other for the minimum the area between them gives the total average gate power dissipation. (A very important parameter in designing of the triggering circuits).
d
Explanation: As the gate characteristics is a plot of Ig vs Vg consisting of two curves one
for the maximum values & other for the minimum the area between them gives the total
average gate power dissipation. (A very important parameter in designing of the
triggering circuits).
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b Explanation: During the delay time only, the collector current flows & base to emitter voltage is zero. Hence the average power can be found, simply by integrating it over the total delay time & dividing by the base time period.
b
Explanation: During the delay time only, the collector current flows & base to emitter
voltage is zero. Hence the average power can be found, simply by integrating it over the
total delay time & dividing by the base time period.
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a Explanation: Vo = √2Vs (1+cosα)/π.
a
See lessExplanation: Vo = √2Vs (1+cosα)/π.