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Transcript 
Chapter 11
Amplifiers: Specifications and
External Characteristics
Chapter 11
Amplifiers: Specifications and
External Characteristics
1. Use various amplifier models to calculate
amplifier performance for given sources
and loads.
2. Compute amplifier efficiency.
3. Understand the importance of input and output
impedances of amplifiers.
4. Determine the best type of ideal amplifier for
various applications.
5. Specify the frequency-response requirements
for various amplifier applications.
6. Understand linear and nonlinear distortion in
amplifiers.
7. Specify the pulse-response parameters of
amplifiers.
8. Work with differential amplifiers and specify
common-mode rejection requirements.
9. Understand the various sources of dc offsets
and design balancing circuits.
BASIC AMPLIFIER
CONCEPTS
Ideally, an amplifier produces an output
signal with identical waveshape as the
input signal, but with a larger amplitude.
vo t   Av vi t 
Inverting versus Noninverting
Amplifiers
Inverting amplifiers have negative voltage
gain, and the output waveform is an
inverted version of the input waveform.
Noninverting amplifiers have positive
voltage gain.
Voltage-Amplifier Model
Current Gain
io
Ai 
ii
io vo RL
Ri
Ai  
 Av
ii
vi Ri
RL
Power Gain
Po
G
Pi
Po Vo I o
2 Ri
G

 Av Ai   Av 
Pi Vi I i
RL
CASCADED AMPLIFIERS
Av  Av1 Av 2
Simplified Models for
Cascaded Amplifier Stages
First, determine the voltage gain of the first
stage accounting for loading by the second
stage.
The overall voltage gain is the product of the
gains of the separate stages.
The input impedance is that of the first stage,
and the output impedance is that of the last
stage.
POWER SUPPLIES AND
EFFICIENCY
Ps  VAA I A  VBB I B
Current-Amplifier Model
Aisc is the current gain of the amplifier
with the output short circuited.
Transconductance-Amplifier Model
Gmsc
iosc

vi
Connect a short circuit across the output
terminals and analyze the circuit to determine
Gmsc.
Transresistance-Amplifier Model
Rmoc
vooc

ii
Open circuit the output terminals and
analyze the circuit to determine Rmoc.
IMPORTANCE OF AMPLIFIER
IMPEDANCES IN VARIOUS
APPLICATIONS
Some applications call for amplifiers with high
input (or output) impedance while others call
for low input (or output) impedance.
Other applications call for amplifiers that have
specific input and/or output impedances.
The proper classification of a given
amplifier depends on the ranges of
source and load impedances with which
the amplifier is used.
FREQUENCY RESPONSE
Vo
Av 
Vi
Determining Complex Gain

vi t   0.1 cos2000t  30



vo t   10 cos2000t  15
Vo
1015
Av 


Vi 0.1  30

 10045

LINEAR WAVEFORM
DISTORTION
If the gain of an amplifier has a different
magnitude for the various frequency
components of the input signal, a form of
distortion known as amplitude distortion
occurs.
Phase Distortion
If the phase shift of an amplifier is not
proportional to frequency, phase
distortion occurs.
Requirements for
Distortionless Amplification
To avoid linear waveform distortion, an
amplifier should have constant gain magnitude
and a phase response that is linear versus
frequency for the range of frequencies
contained in the input signal.
PULSE RESPONSE
Rise Time
0.35
tr 
B
Tilt
P
percentage tilt 
 100%
P
For small amounts of tilt,
percentage tilt  200f LT
TRANSFER CHARACTERISTIC
AND NONLINEAR DISTORTION
The transfer characteristic is a plot of
instantaneous output amplitude versus
instantaneous input amplitude.
Curvature of the transfer characteristic results
in nonlinear distortion.
Harmonic Distortion
For a sinewave input, nonlinear distortion
produces output components having
frequencies that are integer multiples of the
input frequency. v t   V cos t 
i
a
a
vo t   V0  V1 cos a t   V2 cos2 a t   V3 cos3 a t   
V2
D2 
V1
V3
D3 
V1
V4
D4 
V1
Total Harmonic Distortion (THD)
Total harmonic distortion is a specification
that indicates the degree of nonlinear
distortion produced by an amplifier.
D  D  D  D  D 
2
2
2
3
2
4
2
5
DIFFERENTIAL AMPLIFIERS
A differential amplifier has two input terminals:
an inverting input and a noninverting input.
Ideally, a differential amplifier produces an
output that is proportional to the difference
between two input signals.
vid  vi1  vi 2
vo  Ad vid
Common-mode Signal
vicm
1
 vi1  vi 2 
2
Common-Mode Rejection Ratio
vo  Ad vid  Acm vicm
CMRR  20 log
Ad
Acm
OFFSET VOLTAGE,
BIAS CURRENT, AND
OFFSET CURRENT
Real differential amplifiers suffer from
imperfections that can be modeled by
several dc sources: two bias-current
sources, an offset current source, and an
offset voltage source. The effect of these
sources is to add a (usually undesirable) dc
term to the ideal output.
Problem Set
• 4, 13, 17, 22, 25, 34, 40, 47, 55, 58, 67, 68, 74,
78, 82.
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