![]() There are multiple regions in the transconductance curve and they are ohmic, saturation, cutoff, and breakdown regions. The P-channel JFET characteristics or transconductance curve is shown in the figure below which is graphed between drain current and gate-source voltage. Hence, the transistor enters into the breakdown region. If the VDD voltage applied to the drain terminal exceeds the maximum necessary voltage, then the transistor fails to resist the current and thus, the current flows from drain terminal to source terminal. In this cutoff region, there will be no drain current flowing and thus, the N-channel JFET is in OFF condition. In the saturation region, the N-channel junction field effect transistor is in ON condition and active, as maximum current flows because of the gate-source voltage applied. The only region in which transconductance curve shows linear response and drain current is opposed by the JFET transistor resistance is termed as Ohmic region. The N-channel JFET characteristics or transconductance curve is shown in the figure below which is graphed between drain current and gate-source voltage. Thus, by changing the polarity of the gate voltage the drain current can be reduced and then N-channel JFET is said to be in OFF condition. N-Channel Operation of JFETįor turning off the N-channel JFET, the positive bias voltage can be turned off or a negative voltage can be applied to the gate terminal. If the voltage at the gate terminal, VGG is 0V, then there will be maximum current at the drain terminal and N-channel JFET is said to be in ON condition. Thus, current flow is allowed through the drain to source channel. For turning ON a N-channel JFET, positive voltage of VDD has to be applied to the drain terminal of the transistor w.r.t (with respect to) source terminal such that the drain terminal must be appropriately more positive than the source terminal. The working of JFET can be explained by discussing about how to turn on N-channel JFET and how to turn off N-channel JFET. ![]() Operation of JFET can be studied separately for both N-channel and P-channel. Hence, if the transistor is turned on, then we can say that the current flow is primarily because of the holes. The JFET in which holes are primarily composed as the charge carrier is termed as P-channel JFET. P-Channel Junction Field Effect Transistor P-Channel JFET Hence, if the transistor is turned on, then we can say that the current flow is primarily because of the movement of electrons. The JFET in which electrons are primarily composed as the charge carrier is termed as N-channel JFET. N-Channel Junction Field Effect Transistor N-Channel JFET
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