Qn5What is the purpose of using a self-biased circuit for MOSFET amplifiers?

In summary: So in enhancement mode, it is very important to bias the transistor in saturation region.In summary, The transistor operates in saturation region when the gate to source voltage Vgs is greater then the threshold voltage and when the gate to drain voltage is less then the threshold voltage. This is the only difference between depletion and enhancement MOSFETS.
  • #1
cyeokpeng
69
0
Hi,

I know how to bias a BJT transistor to operate in the active region, so that the amplifier circuit can operate as a small-signal amplifier. Two methods
(i) Use biasing resistors to form a self-biasing circuit.
(ii) Use diode biasing, coupled with biasing resistors.

Qn1
However, how do we bias the transistor circuit to act as small signal amplifier, if MOSFETs are used instead?
Design of dc biasing circuit for MOSFET as an amplifier?

I read from my textbook that we need to bias the MOSFET in the saturation region, which is quite different from the BJT amplifier dc biasing design.
The relation of MOSFET in saturation region is
Id = K(Vgs - Vt)^2

where Id = dc drain current
K = a property of MOSFET (What exactly is this?)
Vgs = dc gate-source voltage
Vt = threshold voltage of MOSFET

Qn2
Is there any difference in dc biasing design of n-type enhancement MOSFETs with n-type depletion type MOSFETs? What is the difference?

Qn3
After the MOSFET biasing point is fixed (saturated), we input an small ac signal in the input port, to get an amplified output signal in the output port, with the midband gain depending on the amplifier design.
How is the small signal equivalent circuit model different for enhancement and depletion type MOSFETs?
My answer is, they are essentially the same, but with one slight difference:
vgs for enhancement type is positive, while vgs for depletion type is negative, am I correct?

Qn4
In the small signal model of MOSFET, the ac drain current
id = transconductance * vgs ---Linear, voltage-controlled current source
Why is it this formula, and NOT Id = K(Vgs - Vt)^2?

transconductance = 2K(Vgs - Vt) --Enhancement and Depletion type MOSFET
 
Engineering news on Phys.org
  • #2
U have to bias the MOSFET to have the full output swings. choose your bias point so that in any case it should not go out of saturation.
the equation for mosfet in saturation region is
Id=1/2 U Cox W/L(Vgs - Vt)^2
where U = mobility, Cox= capacitance and W/L = width and legth of mosfet

if u put the value of transconductance in current equation which a reverse of resistance in triode mode...u will get the value of same formula
 
  • #3
Q1) To bias a MOSFET the voltages from the gate to source and from the gate to drain need to be regulated. The device operates in saturation when the gate to source voltage Vgs is greater then the threshold voltage and when the gate to drain voltage is less then the threshold voltage of the transistor. Both conditions must be satisfied.

Q2) The only difference between depletion and enhancement MOSFETS is the value of the threshold voltage, at least its the difference you care about in circuit design.

Q3) Your answer is right

Q4) You do not use Id = K(Vgs - Vt)^2 because you are using a linear approximation of Id = K(Vgs - Vt)^2. If Vgs is only changing by 1mV then the current Id will change in an almost linear way. The linear approximation allows circuit design to be much simpler by only working with linear equations rather then quadratic equations. Keep in mind that it is an approximation though, the larger the voltage swing at the input of the amplifier the less accurate the approximation is.
 
  • #4
nMOS ENHANCEMENT mode is when you aply positive voltage at the gate and it form a channel under the gate ...so it attracts the electronwhereas when u apply negative voltage ta the gate , it actually deplete the region under gate bacoz of negative supply...

For analog design circuit, u hav to keep the device in saturation mode in case...coz to set the threshold voltage in triode is very difficult.
 

FAQ: Qn5What is the purpose of using a self-biased circuit for MOSFET amplifiers?

1. What is a MOSFET and how does it work?

A MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor) is a type of transistor used in electronic circuits to amplify or switch signals. It consists of a metal gate, an insulating layer of oxide, and a semiconducting channel. When a voltage is applied to the gate, it creates an electric field that controls the flow of current through the channel, allowing the MOSFET to act as a switch or amplifier.

2. What is the purpose of DC biasing in MOSFET circuits?

DC biasing is the process of applying a steady voltage or current to a circuit component in order to establish a specific operating point. In MOSFET circuits, DC biasing is used to ensure that the transistor is operating in the desired region, either as a switch or an amplifier, and to prevent it from entering an unstable state.

3. How do you calculate the appropriate DC biasing values for a MOSFET circuit?

The appropriate DC biasing values for a MOSFET circuit can be calculated using the transistor's datasheet and the circuit's desired operating parameters. The key values to consider are the drain-source voltage (VDS), the gate-source voltage (VGS), and the drain current (ID). By selecting appropriate values for these parameters, the MOSFET can be biased to operate in the desired region.

4. What are the common types of DC biasing circuits used for MOSFETs?

The most commonly used DC biasing circuits for MOSFETs are the self-biasing circuit, the voltage divider biasing circuit, and the current source biasing circuit. Each of these circuits has its own advantages and disadvantages, and the selection of the appropriate circuit depends on the specific application and requirements of the circuit.

5. How does temperature affect the DC biasing of a MOSFET circuit?

Temperature can have an impact on the DC biasing of a MOSFET circuit because it can affect the electrical properties of the transistor. As temperature increases, the drain current and voltage thresholds may change, potentially shifting the operating point of the transistor. It is important to consider temperature effects when designing a MOSFET DC biasing circuit to ensure stable and reliable operation.

Similar threads

Replies
3
Views
3K
Replies
2
Views
2K
Replies
4
Views
6K
Replies
8
Views
5K
Replies
3
Views
2K
Replies
2
Views
1K
Replies
4
Views
3K
Replies
13
Views
2K
Back
Top