We have considered the MOSFET in Section 2 and the JFET in Section 4. Within each class are the n-channel and p-channel devices. The MOSFET classification is further subdivided into enhancement and depletion transistors. These combinations lead to six possible types of devices.

A P-Channel MOSFET is a type of MOSFET in which the channel of the MOSFET is composed of a majority of holes as current carriers. When the MOSFET is activated and is on, the majority of the current flowing are holes moving through the channels.

• MOSFET to Switch LED. Most of the circuits use MOSFET as switch compared to JFET due to the advantages offered by it. We can also use switching circuit (to operate the load at particular switching frequency) for the JFETs and MOSFETs for getting the PWM signals based on the load requirements.
• Video explains to you how MOSFETs (metal-oxide-semiconductor field-effect transistor) work and how they are.

This is in contrast to the other type of MOSFET, which are N-Channel MOSFETs, in which the majority ofcurrent carriers are electrons.

Before, we go over the construction of P-Channel MOSFETs, we must go over the 2 types that exist. There are 2 types of P-Channel MOSFETs, enhancement-type MOSFETs and depletion-type MOSFETs.

A depletion-type MOSFET is normally on (maximum current flows from source to drain) when no differencein voltage exists between the gate and source terminals. However, if a voltage is applied to its gate lead, the drain-source channel becomes more resistive, until the gate voltage is so high, the transistor completely shuts off. An enhancement-type MOSFET is the opposite. It is normally off when the gate-source voltage is 0V(VGS=0). However, if a voltage is applied to its gate lead, the drain-source channel becomesless resistive.

In this article, we will go over how both P-Channel enhancement-type and depletion-type MOSFETs are constructed and operate.

How P-Channel MOSFETs Are Constructed Internally

An P-Channel MOSFET is made up of a P channel, which is a channel composed of a majority of hole current carriers. The gate terminals are made up of N-type material.

Depending on the voltage quantity and type (negative or positive)determines how the transistor operates and whether it turns on or off.

How a P-Channel Enhancement-type MOSFET Works

How to Turn on a P-Channel Enhancement Type MOSFET

To turn on a P-Channel Enhancement-type MOSFET, apply a positive voltage VS to the source of the MOSFET and apply a negative voltage to the gate terminal of the MOSFET (the gate must be sufficiently more negative than the threshold voltage across the drain-source region(VGDS). This will allow a current to flow through the source-drain channel.

So with a sufficient positive voltage, VS, to the source and load, and sufficient negative voltage applied to the gate, the P-Channel Enhancement-type MOSFET is fully functional and is in the active 'ON' mode of operation.

How to Turn Off a P-Channel Enhancement Type MOSFET

To turn off a P-channel enhancement type MOSFET, there are 2 steps you can take. You can either cut off the bias positive voltage, VS, that powers the source. Or you can turn off the negative voltagegoing to the gate of the transistor.

How a P-Channel Depletion-type MOSFET Works

How to Turn on a P-Channel Depletion Type MOSFET

To turn on a P-Channel Depletion-Type MOSFET, for maximum operation, the gate voltage feeding the gate terminal should be 0V. With the gate voltage being 0V, the drain current is at is largest value and the transistor is in the active 'ON'region of conduction.

So, again, to turn on a P channel depletion-type MOSFET, positive voltage is applied to the source of the p-channel MOSFET. So we power the source terminal of the MOSFET with VS, a positive voltage supply. With a sufficient positive voltage, VS, and no voltage (0V) applied to the base, the P-channel Depletion-type MOSFET is in maximum operation and has the largest current.

How to Turn Off a P-Channel Depletion Type MOSFET

To turn off a P-channel MOSFET, there are 2 steps you can take. You can either cut off the bias positivevoltage, VDD, that powers the drain. Or you can apply a negative voltage to the gate. When a negativevoltage is applied to the gate, the current is reduced. As the gate voltage, VG, becomes more negative, the current lessens until cutoff, which is when then MOSFET is in the 'OFF' condition. This stops a large source-drain current.

So ,again, as negative voltage is applied to the gate terminal of the P channel depletion-type MOSFET, the MOSFET conducts less and less current across the source-drain terminal. When the gate voltage reaches a certain negative voltage threshold, it shuts the transistor off. Negative voltage shuts the transistor off. This is for a depletion-type P-channel MOSFET.

MOSFET transistors are used for both switching and amplifying applications. MOSFETs are perhaps the most popular transistors used today. Their high input impedance makes them draw very little input current, they are easy to make, can be made very small, and consume very little power.

Related Resources

How to Build a P-Channel MOSFET Switch Circuit
N-Channel MOSFET Basics
N Channel JFET Basics
P Channel JFET Basics
Types of Transistors

A constant-current diode is an electronic device that limits current to a maximal specified value for the device. It is known as a current-limiting diode (CLD) or current-regulating diode (CRD).

It consists of an n-channel JFET with the gate shorted to the source, which functions like a two-terminal current limiter or current source (analogous to a voltage-limiting Zener diode). It allows a current through it to rise to a certain value, and then level off at a specific value. Unlike Zener diodes, these diodes keep the current constant instead of the voltage constant. These devices keep the current flowing through them unchanged when the voltage changes.

Difference Between Transistor And Mosfet

Note that some devices are unidirectional and voltage across the device must have only one polarity for it to operate as a CLD, whereas other devices are bidirectional and can operate properly in either polarity.

Wide-bandgap materials such as silicon carbide have been used in production devices to enable high-voltage applications in the kilovolt range.^[1]

Fet Jfet Mosfet

References[edit]

1. ^'CALY Technologies SiC CLD devices'. CALY Technologies. Retrieved 26 April 2020.

Jfet And Mosfet Difference

External links[edit]

• Advantages of Constant Current Regulators (CCR) in Driving LEDs on YouTube

Diode

• CLD diode datasheet, MCC
• CRD diode datasheet, Semitec
• J500 diode datasheet, Linear Systems / Siliconix / Vishay
• 1N5283 to 1N5314 diode datasheet, Central Semiconductor

JFET

• 2N5457/8/9 & MMBF5457/8/9 JFET datasheet, ON Semiconductor (Former Fairchild)