Audio Amplifier
B.E. PROJECT REPORT
EDA (12817)
Prepared by
Salman Khaliq Bajwa (3746)Hassam Haq ( )
Waqar Khokhar( )
AdvisorAsstt. Professor, Amir Hasan Khan
College of Engineering
PAF-Karachi Institute of Economics & Technology
Karachi
DEDICATION
This report is dedicated to
My Parents, Teachers & Friends,
Whose love, affection and support helped me in bringing my work to this level of
accomplishments; I am also thankful to them for their unconditional support and encouragement
to pursue my interests, even when the interest went beyond the boundaries of field and scope.
Without their support and kindness this work would not have been possible.
ACKNOWLEDEMENT
Praise to Allah the most beneficent and the most merciful
We are grateful to our project advisor Mr. Amir Hasan Khan, for enlightening us with his
precious knowledge and vast experience to benefit us in the future. We also like to thank to our
teachers and lab assistants for their assistance and support.
We would also thank with all gratitude and depth of our hearts to our parents who helped us
not only financially but with integrity too and support us in all our hardships. Finally our sincere
thanks to our institute PAF-KIET, College of Engineering, for providing us the opportunity to
gave us the strength to undertake this research.
Special thanks to all our fellows and friends who lend us a hand throughout this project.
We pray this effort may prove to be the beginning of new era, a era in which Science and
Technology may make great progress in Pakistan and Pakistan may become a part of the
developed nations.
Thank you.
Objective:
The main objective of this is to understand the working of amplifiers.
Purpose:
The purpose of this project is to understand the need and working of amplifiers.
Description:
Before we go into the depth of our project, we first need to understand what is an amplifier
and why do we need it?
An amplifier is a device for increasing the power of a signal by use of an external energy source.
In an electronic amplifier, the input "signal" is usually a voltage or a current. Other types exist; a
fluidic amplifier increases the power of signals represented as flow of as or liquid, for example.
Amplifiers may be classified in a variety of ways depending on their application, the frequency
range they cover, or the active devices used. Ideally an amplifier increases the power of a signal
without otherwise altering it; practical amplifiers have finite distortion and noise which they
invariably add to the signal.
The quality of an amplifier can be characterized by a number of specifications, listed below.
1. Gain
The gain of an amplifier is the ratio of output to input power or amplitude, and is usually
measured in decibels. (When measured in decibels it is logarithmically related to the power
ratio: G(dB)=10 log(Pout /(Pin)). RF amplifiers are often specified in terms of the maximum power
gain obtainable, while the voltage gain of audio amplifiers and instrumentation amplifiers will
be more often specified (since the amplifier's input impedance will often be much higher than
the source impedance, and the load impedance higher than the amplifier's output impedance).
For example, an audio amplifier with a gain given as 20 dB will have a voltage gain of ten (but a
power gain of 100 would only occur in the event the input and output impedances were
identical).
If two equivalent amplifiers are being compared, the amplifier with higher gain settings would
be more sensitive as it would take less input signal to produce a given amount of power.
2. Bandwidth
The bandwidth of an amplifier is the range of frequencies for which the amplifier gives
"satisfactory performance". The definition of "satisfactory performance" may be different for
different applications. However, a common and well-accepted metric is the half power points
(i.e. frequency where the power goes down by half its peak value) on the output vs. frequency
curve. Therefore bandwidth can be defined as the difference between the lower and upper half
power points. This is therefore also known as the −3 dB bandwidth. Bandwidths (otherwise
called "frequency responses") for other response tolerances are sometimes quoted (−1 dB, −6
dB etc.) or "plus or minus 1dB" (roughly the sound level difference people usually can detect).
3. Efficiency
Efficiency is a measure of how much of the power source is usefully applied to the amplifier's
output. Class A amplifiers are very inefficient, in the range of 10–20% with a max efficiency of
25% for direct coupling of the output. Inductive coupling of the output can raise their efficiency
to a maximum of 50%.
Drain efficiency is the ratio of output RF power to input DC power when primary input DC
power has been fed to the drain of an FET. Based on this definition, the drain efficiency cannot
exceed 25% for a class A amplifier that is supplied drain bias current through resistors (because
RF signal has its zero level at about 50% of the input DC). Manufacturers specify much higher
drain efficiencies, and designers are able to obtain higher efficiencies by providing current to
the drain of the transistor through an inductor or a transformer winding. In this case the RF
zero level is near the DC rail and will swing both above and below the rail during operation.
While the voltage level is above the DC rail current is supplied by the inductor.
4. Linearity
An ideal amplifier would be a totally linear device, but real amplifiers are only linear within
limits.
When the signal drive to the amplifier is increased, the output also increases until a point is
reached where some part of the amplifier becomes saturated and cannot produce any more
output; this is called clipping, and results in distortion.
In most amplifiers a reduction in gain takes place before hard clipping occurs; the result is a
compression effect, which (if the amplifier is an audio amplifier) sounds much less unpleasant to
the ear. For these amplifiers, the 1 dB compression point is defined as the input power (or
output power) where the gain is 1 dB less than the small signal gain. Sometimes this
nonlinearity is deliberately designed in to reduce the audible unpleasantness of hard clipping
under overload.
Ill effects of nonlinearity can be reduced with negative feedback.
5. Noise
This is a measure of how much noise is introduced in the amplification process. Noise is an
undesirable but inevitable product of the electronic devices and components; also, much noise
results from intentional economies of manufacture and design time. The metric for noise
performance of a circuit is noise figure or noise factor. Noise figure is a comparison between
the output signal to noise ratio and the thermal noise of the input signal.
6. Slew rate
Slew rate is the maximum rate of change of the output, usually quoted in volts per second (or
microsecond). Many amplifiers are ultimately slew rate limited (typically by the impedance of a
drive current having to overcome capacitive effects at some point in the circuit), which
sometimes limits the full power bandwidth to frequencies well below the amplifier's small-
signal frequency response.
7. Stability
Stability is an issue in all amplifiers with feedback, whether that feedback is added intentionally
or results unintentionally. It is especially an issue when applied over multiple amplifying stages.
Stability is a major concern in RF and microwave amplifiers. The degree of an amplifier's
stability can be quantified by a so-called stability factor. There are several different stability
factors, such as the Stern stability factor and the Linvil stability factor, which specify a condition
that must be met for the absolute stability of an amplifier in terms of its two-port parameters.
Audio Amplifier:
An audio amplifier is an electronic amplifier that amplifies low-power audio signals (signals
composed primarily of frequencies between 20 - 20 000 Hz, the human range of hearing) to a
level suitable for driving loudspeakers and is the final stage in a typical audio playback chain.
Circuit:
Schematic: