c Explanation: String efficiency = 3300/(6 x 600) = 98.54.
c
Explanation: String efficiency = 3300/(6 x 600) = 98.54.
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c Explanation: String efficiency = 3300/(6 x 600) = 98.54.
c
Explanation: String efficiency = 3300/(6 x 600) = 98.54.
Answer: c Explanation: String efficiency = 3300/(6 x 600) = 98.54
Answer: c
Explanation: String efficiency = 3300/(6 x 600) = 98.54
Answer: b Explanation: Higher the value of anode-cathode forward voltage, lower the gate requirements of the device.
Answer: b
Explanation: Higher the value of anode-cathode forward voltage, lower the gate
requirements of the device.
Answer: c Explanation: In forward voltage triggering the middle junction breaks down without any gate signal and pushes the device into the conducting state. This method can permanently damage the J2 junction and make the device useless.
Answer: c
Explanation: In forward voltage triggering the middle junction breaks down without any
gate signal and pushes the device into the conducting state. This method can
permanently damage the J2 junction and make the device useless.
Answer: b Explanation: It is the forward voltage at which the middle junction breaks down without any gate signal and pushes the device into the conducting state.
Answer: b
Explanation: It is the forward voltage at which the middle junction breaks down without
any gate signal and pushes the device into the conducting state.
Answer: d Explanation: The drift layer which is a n– layer determines the voltage blocking capabilities.
Answer: d
Explanation: The drift layer which is a n– layer determines the voltage blocking
capabilities.
Answer: a Explanation: Finger voltage is the minimum value of Vak (anode to cathode voltage) to turn on the device with gate triggering, it is to be avoided for accidental turn-on of the device.
Answer: a
Explanation: Finger voltage is the minimum value of Vak (anode to cathode voltage) to
turn on the device with gate triggering, it is to be avoided for accidental turn-on of the
device.
Answer: c Explanation: It is peak repetitive reverse voltage/ the maximum value of input voltage(Vm).
Answer: c
Explanation: It is peak repetitive reverse voltage/ the maximum value of input
voltage(Vm).
a Explanation: Load line is nothing but Rs Es = 16V Vg.Ig = 0.5 Rs = 128 We have Es = Ig x Rs + Vg.
a
Explanation: Load line is nothing but Rs
Es = 16V
Vg.Ig = 0.5
Rs = 128
We have Es = Ig x Rs + Vg.
c Explanation: String efficiency = 3300/(6 x 600) = 98.54.
c
See lessExplanation: String efficiency = 3300/(6 x 600) = 98.54.