Transcript Chapter 21
Bipolar Transistors
Chapter 21
Introduction
An Overview of Bipolar Transistors
Bipolar Transistor Operation
Bipolar Transistor Characteristics
Summary of Bipolar Transistor Characteristics
Bipolar Transistor Amplifiers
Other Bipolar Transistor Applications
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Introduction
21.1
Bipolar transistors are one of the main
‘building-blocks’ in electronic systems
They are used in both analogue and digital circuits
They incorporate two pn junctions and are
sometimes known as bipolar junction transistors
or BJTs
Here will refer to them simply as bipolar transistors
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An Overview of Bipolar Transistors
21.2
While control in a FET is due to an electric field,
control in a bipolar transistor is generally considered
to be due to an electric current
– current into one terminal
determines the current
between two others
– as with a FET, a
bipolar transistor
can be used as a
‘control device’
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Notation
– bipolar transistors are 3
terminal devices
collector (c)
base (b)
emitter (e)
– the base is the control input
– diagram illustrates the
notation used for labelling
voltages and currents
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Relationship between the collector current and the
base current in a bipolar transistor
– characteristic is
approximately linear
– magnitude of collector
current is generally
many times that of the
base current
– the device provides
current gain
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Construction
– two polarities:
npn and pnp
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Bipolar Transistor Operation
21.3
We will consider npn transistors
– pnp devices are similar but with different polarities of
voltage and currents
– when using npn transistors
collector is normally more positive than the emitter
VCE might be a few volts
device resembles two back-to-back diodes – but has very
different characteristics
with the base open-circuit negligible current flows from the
collector to the emitter
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Now consider what happens when a positive voltage
is applied to the base (with respect to the emitter)
– this forward biases the base-emitter junction
– the base region is light doped and very thin
– because it is likely doped, the current produced is
mainly electrons flowing from the emitter to the base
– because the base region is thin, most of the electrons
entering the base get swept across the base-collector
junction into the collector
– this produces a collector current that is much larger than
the base current – this gives current amplification
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Transistor action
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Bipolar Transistor Characteristics
21.4
Behaviour can be described by the current gain, hfe
or by the transconductance, gm of the device
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Transistor configurations
– transistors can be used in a
number of configurations
– most common is as shown
– emitter terminal is common
to input and output circuits
– this is a common-emitter
configuration
– we will look at the
characteristics of the device
in this configuration
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Input characteristics
– the input takes the
form of a forwardbiased pn junction
– the input
characteristics are
therefore similar to
those of a
semiconductor diode
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Output characteristics
– region near to the
origin is the
saturation region
– this is normally
avoided in linear
circuits
– slope of lines
represents the
output resistance
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Transfer characteristics
– can be described by either the current gain or by the
transconductance
– DC current gain hFE or is given by IC / IB
– AC current gain hfe is given by ic / ib
– transconductance gm is given approximately by
gm 40IC 40 IE siemens
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Equivalent circuits for a bipolar transistor
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Summary of Bipolar Transistor Characteristics
21.5
Bipolar transistors have three terminals: collector,
base and emitter
The base is the control input
Two polarities of device: npn and pnp
The collector current is controlled by the base
voltage/current IC = hFEIB
Behaviour is characterised by the current gain or the
transconductance
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Bipolar Transistor Amplifiers
21.6
A simple transistor amplifier
– RB is used to ‘bias’ the
transistor by injecting an
appropriate base current
– C is a coupling capacitor
and is used to couple the
AC signal while preventing
external circuits from
affecting the bias
– this is an AC-coupled amplifier
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AC-coupled amplifier
– VB is set by the conduction voltage of the base-emitter
junction and so is about 0.7 V
– voltage across RB is thus VCC – 0.7
– this voltage divided by RB gives the base current IB
– the collector current is then given by IC = hFEIB
– the voltage drop across RC is given by IC RC
– the quiescent output voltage is therefore
Vo = VCC - IC RC
– output is determined by hFE which is very variable
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Negative feedback amplifiers
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Example – see Example 21.2 from course text
Determine the
quiescent output
voltage of this
circuit
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Base current is small, so
VB VCC
R2
10 k
10
2. 7 V
R1 R2
27 k 10 k
Emitter voltage
VE = VB – VBE = 2.7 – 0.7 = 2.0 V
Emitter current
IE
VE 2.0 V
2 mA
RE 1 k
Since IB is small, collector current IC IE = 2 mA
Output voltage = VCC – ICRC = 10 - 2 mA 2.2 k = 5.6 V
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A common-collector amplifier
–
–
–
–
unity gain
high input resistance
low output resistance
a very good
buffer amplifier
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Other Bipolar Transistor Applications
21.7
A phase splitter
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A voltage regulator
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A logical switch
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Key Points
Bipolar transistors are widely used in both analogue and
digital circuits
They can be considered as either voltage-controlled or
current-controlled devices
Their characteristics may be described by their gain or by
their transconductance
Feedback can be used to overcome problems of variability
The majority of circuits use transistors in a common-emitter
configuration where the input is applied to the base and the
output is taken from the collector
Common-collector circuits make good buffer amplifiers
Bipolar transistors are used in a wide range of applications
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