Transistor Amplifier Configuration this document will tell us about the transistor amplification.

1. Bipolar Transistor
Configurations

2. As the Bipolar Transistor is a three-terminal device, there are
basically three possible ways to connect it within an electronic circuit
with one terminal being common to both the input and output. Each
method of connection responding differently to its input signal within
a circuit as the static characteristics of the transistor vary with each
circuit arrangement.
• Common Base Configuration – has Voltage Gain but no
Current Gain
• Common Emitter Configuration – has both Current and
Voltage Gain
• Common Collector Configuration – has Current Gain but no
Voltage Gain

3. Common Base Amplifier

4. • The common-base (CB) amplifier provides high voltage gain with
a maximum current gain of 1.
• Since it has a low input resistance, the CB amplifier is the most
appropriate type for certain applications where sources tend to
have very low-resistance outputs.

8. Characteristics of Common Base
Transistor Amplifier
Configurations Common base
Phase Angle Zero (0°)
Input terminal Emitter
Output terminal Collector
Voltage gain High
Current gain Low (ratio of collector current & emitter current)
Power gain Low
Input impedence Low
Output
impedence
High

9. • To describe the behavior of common-base amplifiers requires two set of
characteristics:
- Input or driving point characteristics.
- Output or collector characteristics
• The output characteristics has 3 basic regions:
- Active region –defined by the biasing arrangements
- Cutoff region – region where the collector current is 0A
- Saturation region- region of the characteristics to the left of VCB = 0V

11. Alpha():
• In the dc mode the level of IC and IE due to the
majority carriers are related by a quantity called alpha
=
So,
IC = IE
• For ac situations where the point of operation moves on
the characteristics curve, an ac alpha defined by
• Alpha a common base current gain factor that shows
the efficiency by calculating the current percent from
current flow from emitter to collector. The value of  is
typical from 0.9 ~ 0.998.
E
C
I
I
E
C
I
I





12. Common Emitter Amplifier

22. Characteristics of Common Emitter Transistor
Amplifier

23. Common Emitter Transistor Amplifier

24. Common Collector Amplifier

25. • The common-collector (CC) amplifier is usually
referred to as an emitter-follower (EF).
• The input is applied to the base through a
coupling capacitor, and the output is at the
emitter.
• The voltage gain of a CC amplifier is
approximately 1, and its main advantages are its
high input resistance and current gain.

26. • An emitter-follower circuit with voltage-divider
bias is shown in Figure 6–25.
• Notice that the input signal is capacitively coupled
to the base, the output signal is capacitively
coupled from the emitter, and the collector is at ac
ground.
• There is no phase inversion, and the output is
approximately the same amplitude as the input.

32. Characteristics of Common Collector
Transistor Amplifier

33. CHARACTERISTICS COMMON BASE
COMMON
EMITTER
COMMON
COLLECTOR
Current Gain
Nearly unity
(α)
High (β) Highest (1+β)
Voltage Gain High Very high Nearly unity
Power Gain Moderate Highest Lowest
Input Impedance Lowest Moderate Highest
Output Impedance Highest Moderate Lowest
Phase Reversal No Yes No
Comparison of Amplifiers Configuration