Based on Configurations
Any transistor amplifier, uses a transistor to amplify the signals which is connected in one of the three configurations. For an amplifier it is a better state to have a high input impedance, in order to avoid loading effect in Multi-stage circuits and lower output impedance, in order to deliver maximum output to the load. The voltage gain and power gain should also be high to produce a better output.
Let us now study different configurations to understand which configuration suits better for a transistor to work as an amplifier.
CB Amplifier
The amplifier circuit that is formed using a CB configured transistor combination is called as CB amplifier.
Construction
The common base amplifier circuit using NPN transistor is as shown below, the input signal being applied at emitter base junction and the output signal being taken from collector base junction.
The emitter base junction is forward biased by VEE and collector base junction is reverse biased by VCC. The operating point is adjusted with the help of resistors Re and Rc. Thus the values of Ic, Ib and Icb are decided by VCC, VEE, Re and Rc.
Operation
When no input is applied, the quiescent conditions are formed and no output is present. As Vbe is at negative with respect to ground, the forward bias is decreased, for the positive half of the input signal. As a result of this, the base current IB also gets decreased.
The below figure shows the CB amplifier with self-bias circuit.
As we know that,
The emitter base junction is forward biased by VEE and collector base junction is reverse biased by VCC. The operating point is adjusted with the help of resistors Re and Rc. Thus the values of Ic, Ib and Icb are decided by VCC, VEE, Re and Rc.
Operation
When no input is applied, the quiescent conditions are formed and no output is present. When positive half of the signal is being applied, the voltage between base and emitter Vbe is increased because it is already positive with respect to ground.
As forward bias increases, the base current too increases accordingly. Since IC= βIB, the collector current increases as well.
The following circuit diagram shows a CE amplifier with self-bias circuit.
The collector current when flows through RC, the voltage drop increases.
The emitter base junction is forward biased by VEE and collector base junction is reverse biased by VCC. The Q-values of Ib and Ie are adjusted by Rb and Re.
Operation
When no input is applied, the quiescent conditions are formed and no output is present. When positive half of the signal is being applied, the forward bias is increased because Vbe is positive with respect to collector or ground. With this, the base current IB and the collector current IC are increased.
The following circuit diagram shows a CC amplifier with self-bias circuit.
Consequently, the voltage drop across Re i.e. the output voltage is increased. As a result, positive half cycle is obtained. As the input and output are in phase, there is no phase reversal.
If CC configuration is considered for amplification, though CC amplifier has better input impedance and lower output impedance than CE amplifier, the voltage gain of CC is very less which limits its applications to impedance matching only.
Comparison between CB CE CC Amplifiers
Let us compare the characteristic details of CB, CE, and CC amplifiers.
Characteristic |
CE |
CB |
CC |
Input resistance |
Low (1K to 2K) |
Very low (30-150 Ω) |
High (20-500 KΩ) |
Output resistance |
Large (≈ 50 K) |
High (≈ 500 K) |
Low (50-1000 KΩ) |
Current gain |
B high |
α < 1 |
High (1 + β) |
Voltage gain |
High (≈ 1500) |
High (≈ 1500) |
Less than one |
Power gain |
High (≈ 10,000) |
High (≈ 7500) |
Low (250-500) |
Phase between input and output |
reversed |
same |
same |
Due to the compatibility and characteristic features, the common-emitter configuration is mostly used in amplifier circuits.