What is a MOSFET : Working and Its Applications The MOSFET (Metal Oxide Semiconductor Field Effect Transistor) transistor is a semiconductor device that is widely used for switching purposes and for the amplification of electronic signals in electronic devices. A MOSFET is either a core or integrated circuit where it is designed and fabricated in a single chip because the device is available in very small sizes. The introduction of the MOSFET device has brought a change in the domain of switching in electronics. Let us go with a detailed explanation of this concept. What is MOSFET? A MOSFET is a four-terminal device having source(S), gate (G), drain (D) and body (B) terminals. In general, The body of the MOSFET is in connection with the source terminal thus forming a three-terminal device such as a field-effect transistor. MOSFET is generally considered as a transistor and employed in both the analog and digital circuits. This is the basic introduction to MOSFET. And the general structure of this device is as below : MOSFET From the above MOSFET structure, the functionality of MOSFET depends on the electrical variations happening in the channel width along with the flow of carriers (either holes or electrons). The charge carriers enter into the channel through the source terminal and exit via the drain. The width of the channel is controlled by the voltage on an electrode which is called the gate and it is located in between the source and the drain. It is insulated from the channel near an extremely thin layer of metal oxide. The MOS capacity that exists in the device is the crucial section where the entire operation is across this. MOSFET With Terminals A MOSFET can function in two ways Depletion Mode Enhancement Mode Depletion Mode When there is no voltage across the gate terminal, the channel shows its maximum conductance. Whereas when the voltage across the gate terminal is either positive or negative, then the channel conductivity decreases. Please refer to this link to know more about Depletion Mode MOSFET Enhancement Mode When there is no voltage across the gate terminal, then the device does not conduct. When there is the maximum voltage across the gate terminal, then the device shows enhanced conductivity. Enhancement Mode Working Principle of MOSFET The main principle of the MOSFET device is to be able to control the voltage and current flow between the source and drain terminals. It works almost like a switch and the functionality of the device is based on the MOS capacitor. The MOS capacitor is the main part of MOSFET. The semiconductor surface at the below oxide layer which is located between the source and drain terminal can be inverted from p-type to n-type by the application of either a positive or negative gate voltages respectively. When we apply a repulsive force for the positive gate voltage, then the holes present beneath the oxide layer are pushed downward with the substrate. The depletion region populated by the bound negative charges which are associated with the acceptor atoms. When electrons are reached, a channel is developed. The positive voltage also attracts electrons from the n+ source and drain regions into the channel. Now, if a voltage is applied between the drain and source, the current flows freely between the source and drain and the gate voltage controls the electrons in the channel. Instead of the positive voltage, if we apply a negative voltage, a hole channel will be formed under the oxide layer. MOSFET Block Diagram P-Channel MOSFET The P- channel MOSFET has a P- Channel region located in between the source and drain terminals. It is a four-terminal device having the terminals as gate, drain, source, and body. The drain and source are heavily doped p+ region and the body or substrate is of n-type. The flow of current is in the direction of positively charged holes. When we apply the negative voltage with repulsive force at the gate terminal, then the electrons present under the oxide layer are pushed downwards into the substrate. The depletion region populated by the bound positive charges which are associated with the donor atoms. The negative gate voltage also attracts holes from the p+ source and drain region into the channel region. Please refer to this link to know more about – P-Channel MOSFET. Depletion Mode P Channel P Channel Enhanced Mode N- Channel MOSFET The N-Channel MOSFET has an N- channel region located in between the source and drain terminals. It is a four-terminal device having the terminals as gate, drain, source, body. In this type of Field Effect Transistor, the drain and source are heavily doped n+ region and the substrate or body are of P-type. The current flow in this type of MOSFET happens because of negatively charged electrons. When we apply the positive voltage with repulsive force at the gate terminal then the holes present under the oxide layer are pushed downward into the substrate. The depletion region is populated by the bound negative charges which are associated with the acceptor atoms. Upon the reach of electrons, the channel is formed. The positive voltage also attracts electrons from the n+ source and drain regions into the channel. Now, if a voltage is applied between the drain and source the current flows freely between the source and drain and the gate voltage controls the electrons in the channel. Instead of positive voltage if we apply negative voltage then a hole channel will be formed under the oxide layer. Please refer to this link to know more about – N-Channel MOSFET. Enhancement Mode N Channel MOSFET Regions of Operation To the most general scenario, the operation of this device happens mainly in three regions and those are as follows: Cut-off Region – It is the region where the device will be in the OFF condition and there zero amount of current flow through it. Here, the device functions as a basic switch and is so employed as when they are necessary to operate as electrical switches. Saturation Region – In this region, the devices will have their drain to source current value as constant without considering the enhancement in the voltage across the drain to source. This happens only once when the voltage across the drain to source terminal increases more than the pinch-off voltage value. In this scenario, the device functions as a closed switch where a saturated level of current across the drain to source terminals flows. Due to this, the saturation region is selected when the devices are supposed to perform switching. Linear/Ohmic Region – It is the region where the current across the drain to source terminal enhances with the increment in the voltage across the drain to source path. When the MOSFET devices function in this linear region, they perform amplifier functionality. Let us now consider the switching characteristics of MOSFET A semiconductor too such as MOSFET or Bipolar Junction Transistor is basically functioned as switches in two scenarios one is ON state and the other is OFF state. To consider this functionality, let us have a look at the ideal and practical characteristics of the MOSFET device. Ideal Switch Characteristics When a MOSFET is supposed to function as an ideal switch, it should hold the below properties and those are In the ON condition, there has to be the current limitation that it carries In the OFF condition, blocking voltage levels should not hold any kind of limitations When the device functions in ON state, the voltage drop value should be null The resistance in OFF state should be infinite There should be no restrictions on the speed of operation Practical Switch Characteristics As the world is not just stuck to ideal applications, the functioning of MOSFET is even applicable for practical purposes. In the practical scenario, the device should hold the below properties In the ON condition, the power managing abilities should be limited which means that the flow of conduction current has to be restricted. In the OFF state, blocking voltage levels should not be limited Turning ON and OFF for finite times restricts the limiting speed of the device and even limits the functional frequency In the ON condition of the MOSFET device, there will be minimal resistance values where this results in the voltage drop in forwarding bias. Also, there exists finite OFF state resistance that delivers reverse leakage current When the device is performing in practical characteristics, it loses power on ON and OFF conditions. This happens even in the transition states too. Example of MOSFET as a Switch In the below circuit arrangement, an enhanced mode and N-channel MOSFET are being used to switch a sample lamp with the conditions ON and OFF. The positive voltage at the gate terminal is applied to the base of the transistor and the lamp moves into ON condition and here VGS =+v or at zero voltage level, the device turns to OFF condition where VGS=0. MOSFET As Switch If the resistive load of the lamp was to be replaced by an inductive load and connected to the relay or diode which is protected to the load. In the above circuit, it is a very simple circuit for switching a resistive load such as a lamp or LED. But when using MOSFET as a switch either with inductive load or capacitive load, then protection is required for the MOSFET device. If in the case when the MOSFET is not protected, it may lead to damage of the device. For the MOSFET to operate as an analog switching device, it needs to be switched between its cutoff region where VGS =0 and saturation region where VGS =+v. MOSFET can also function as a transistor and it is abbreviated as Metal Oxide Silicon Field Effect Transistor. Here, the name itself indicated that the device can be operated as a transistor. It will have P-channel and N-channel. The device is connected in such a way using the four source, gate, and drain terminals and a resistive load of 24Ω is connected in series with an ammeter, and a voltage meter is connected across the MOSFET. In the transistor, the current flow in the gate is in a positive direction and the source terminal is connected to ground. Whereas in bipolar junction transistor devices, the current flow is across the base-to-emitter path. But in this device, there is no current flow because there is a capacitor at the beginning of the gate, it just requires only voltage. This can be happened by proceeding with the simulation process and by switching ON/OFF. When the switch is ON there is no current flow across the circuit, when the resistance of 24Ω and 0.29 of ammeter voltage are connected, then we find the negligible voltage drop across the source because there is +0.21V across this device. The resistance between drain and source is termed as RDS. Due to this RDS, the voltage drop appears when there is current flow in the circuit. RDS fuvaries based on the type of the device (it can vary in between 0.001, 0.005, and 0.05 based on the type of voltage. The functionality of the MOSFET can be better understood if you go through the below list of circuits using MOSFET. These circuits can be tried on the breadboard as well at home. Voltage Regulator with MOSFET. Solar Tracker with MOSFET. Temperature Controlled Fan with MOSFET. Light Dimming Circuit with MOSFET. Motor Speed Control with MOSFET. Few of the concepts to learn are : 1). How To Choose MOSFET as Switch? There are few conditions to be observed while selecting the MOSFET as a switch and those are a follows: Usage of polarity either P or N channel A maximum rating of operating voltage and current values Increased Rds ON which means that resistance at Drain to Source terminal when the channel is completely open Enhanced operational frequency Packing kind is of To-220 and DPAck and many others. 2). What is MOSFET Switch Efficiency? The main restriction at the time of operating MOSFET as a switching device is the enhanced drain current value that the device can be capable of. It means that RDS in ON condition is the crucial parameter which decides the switching capability of the MOSFET. It is represented as the ratio of drain-source voltage to that of drain current. It has to be calculated only in the ON state of the transistor. 3). Why MOSFET Switch is Used in Boost Converter? In general, a boost converter needs a switching transistor for the operation of the device. So, as switching transistor MOSFETs are used. These devices are used to know the current value and voltage values. Also, considering the switching speed and cost, these are extensively employed. In the same way, MOSFET can also be used in multiple ways. and those are MOSFET as a switch for LED remove_circle_outline MOSFET as a switch for Arduino MOSFET switch for ac load MOSFET switch for dc motor MOSFET switch for negative voltage MOSFET as a switch with Arduino MOSFET as a switch with a microcontroller MOSFET switch with hysteresis MOSFET as switch diode and active resistor MOSFET as a switch equation MOSFET switch for airsoft MOSFET as switch gate resistor MOSFET as a switching solenoid MOSFET switch using an optocoupler MOSFET switch with hysteresis Application of MOSFET as a Switch One of the foremost examples of this device is it is used as a switch is automatic brightness control in street lights. These days, many of the lights that we observe on highways consist of high-intensity discharge lamps. But using HID lamps consumes increased energy levels. The brightness cannot be limited based on the requirement and because of this there has to be a switch for the alternative lighting method and it is LED. Using of LED system will overcome the disadvantages of high-intensity lamps. The main concept behind the construction of this was to control the lights directly on highways by making use of a microprocessor. MOSFET Application as Switch This can be achieved just by modifying the clock pulses. Based on the necessity, this device is used for switching lamps. It consists of a raspberry pi board where it is included with a processor for managing. Here, LEDs can be substituted in the place of HIDs and these have a connection with the processor through MOSFET. The microcontroller delivers corresponding duty cycles and then switches to MOSFET to provide a high level of intensity. Advantages Few of the advantages are : It generates enhanced efficiency even when functioning at minimal voltage levels There is no presence of gate current this creates more input impedance which further provides increased switching speed for the device These devices can function at minimal power levels and uses minimal current Disadvantages Few of the disadvantages are : When these devices are functioned at overload voltage levels, it creates instability of the device As because the devices have a thin oxide layer, this may create damage to the device when stimulated by the electrostatic charges Applications The applications of MOSFET are Amplifiers made of MOSFET are extremely employed in extensive frequency applications The regulation for DC motors are provided by these devices As because these have enhanced switching speeds, it acts as perfect for the construction of chopper amplifiers Functions as a passive component for various electronic elements. In the end, it can be concluded that the transistor requires current whereas MOSFET requires a voltage. The driving requirement for the MOSFET is much better, much simpler as compared to a BJT. And also know How do I wire a Mosfet to a switch? Photo Credits MOSFET by wikimedia MOSFET Block Diagram by calvin Share This Post: Facebook Twitter Google+ LinkedIn Pinterest Post navigation ‹ Previous RS232 – Basics, Applications and InterfacingNext › Embedded System Design Process Related Content Light-Activated Switch with MOSFET Voltage Regulator with MOSFET Solar Tracker with MOSFET Temperature Controlled Fan with MOSFET Comments are closed.