MOSFET Common Source Amplifier with Source Degeneration

In summary, the small signal voltage gain does not collapse as we increase the AC input voltage. The expression Av= (gm * Rd) / (1 + gm Rs) only contains constants, and the gain remains fairly constant as long as the signals stay sinusoidal. Small signals mean that the FET is being driven linearly. If the FET is driven into non-linear regions, the signal is no longer a small signal. The circuit in Wikipedia does not allow for any gate to source bias voltage, but a circuit with a gate to source resistor is needed. Dropbox.com is a safe and free program for file sharing.
  • #1
SearchDS
1
0
Why does the small signal voltage gain collapse as we increase the AC input voltage?


Voltage gain = Av = (output voltage) / (input voltage). Both small signal (AC).

When you draw the small signal circuit using T-Model, you can find that
Av= (gm * Rd) / (1 + gm Rs)

gm being the the trans-conductance.

Don't need an answer that says "Because the input voltage is in the denominator"
Since as we increase the input voltage, the output voltage will increase also, but not in the same ratio.


You can see the circuit here:
http://en.wikipedia.org/wiki/Common_source
 
Engineering news on Phys.org
  • #2
Why does the small signal voltage gain collapse as we increase the AC input voltage?

It doesn't. The expression Av= (gm * Rd) / (1 + gm Rs) only contains constants.

In fact, the gain gets very close to the ratio of Rd / Rs and is fairly constant as long as the signals stay sinusoidal.

Small signals mean just that. If you drive the FET into non linear regions then the signal is no longer a small signal.

The circuit in Wikipedia does not allow for any gate to source bias voltage. To do this, you need a circuit like this:
[PLAIN]http://dl.dropbox.com/u/4222062/FET%20amp%20with%20source%20R.PNG
 
Last edited by a moderator:
  • #3
vk6kro said:
Why does the small signal voltage gain collapse as we increase the AC input voltage?

It doesn't. The expression Av= (gm * Rd) / (1 + gm Rs) only contains constants.

In fact, the gain gets very close to the ratio of Rd / Rs and is fairly constant as long as the signals stay sinusoidal.

Small signals mean just that. If you drive the FET into non linear regions then the signal is no longer a small signal.

The circuit in Wikipedia does not allow for any gate to source bias voltage. To do this, you need a circuit like this:
[PLAIN]http://dl.dropbox.com/u/4222062/FET%20amp%20with%20source%20R.PNG[/QUOTE]

I am just checking out the dropbox.com. Is it save? I download the program but have not run it yet, want to check with you first. What is the catch if it is free?
 
Last edited by a moderator:

1. What is a MOSFET Common Source Amplifier with Source Degeneration?

A MOSFET Common Source Amplifier with Source Degeneration is a type of electronic circuit that uses a MOSFET (metal-oxide-semiconductor field-effect transistor) as the amplifying device. It is designed to amplify small AC signals and is commonly used in audio and radio frequency applications.

2. How does Source Degeneration affect the performance of a MOSFET Common Source Amplifier?

Source Degeneration refers to the addition of a resistor in series with the source of the MOSFET in the amplifier circuit. This resistor helps to stabilize the amplifier's gain and improve its linearity. It also reduces the effect of variations in the MOSFET's characteristics, making the amplifier more reliable.

3. What are the advantages of using a MOSFET Common Source Amplifier with Source Degeneration?

The main advantage of using this type of amplifier is that it provides a high input impedance, which means it can be used with a wide range of input signals without affecting the original signal. It also offers a good voltage gain, low noise, and low distortion, making it suitable for audio and RF applications.

4. What are the limitations of a MOSFET Common Source Amplifier with Source Degeneration?

One limitation of this type of amplifier is that it requires a DC power supply to operate, which can add complexity and cost to the circuit. It is also more sensitive to temperature changes and can be affected by external electromagnetic interference. Additionally, the source degeneration resistor can reduce the overall gain of the amplifier.

5. How can the performance of a MOSFET Common Source Amplifier with Source Degeneration be optimized?

The performance of this type of amplifier can be optimized by carefully selecting the values of the source degeneration resistor and the DC biasing circuit. Proper heat sinking and shielding can also help improve performance. Additionally, using high-quality components and careful circuit design can help minimize noise and distortion.

Similar threads

Differential Amplifier Common Mode Thevenin Equivalent
    • Electrical Engineering
Replies
1
Views
1K
Amplifier Circuit help, impedance matching
    • Electrical Engineering
Replies
20
Views
663
Sources of voltage ripple in buck converter
    • Electrical Engineering
Replies
13
Views
2K
Thoughts for a low-power 60Hz 120Vrms signal generator please
    • Electrical Engineering
2
Replies
47
Views
3K
Class A Amplifier Sinusoidal Input/Output Relation
    • Electrical Engineering
Replies
3
Views
3K
"Class-B" Audio Power Amp with "Current Pumping"
    • Electrical Engineering
Replies
26
Views
2K
Alternator torque when connected to a phase-shifted AC source
    • Electrical Engineering
Replies
3
Views
554
Good resources to practice transistor amplifiers?
    • Electrical Engineering
Replies
3
Views
1K
DC Blocking Capacitor: Solving a Photodiode Circuit Problem
    • Electrical Engineering
Replies
24
Views
3K
Design of a CW multiplier circuit
    • Electrical Engineering
Replies
22
Views
2K

Hot Threads

Recent Insights

Back
Top