Title:The PNP Transister
A PNP Transistor Circuit
Transistor Matching
Identifying the PNP Transistor
Transistor Resistance Values for a PNP
Transistor and a NPN Transistor
The PNP
Transistor is the
exact opposite to the NPN Transistor device we looked at in the previous
tutorial. Basically, in this type of transistor construction the two diodes are
reversed with respect to the NPN type giving a Positive-Negative-Positive
type configuration, with the arrow which also defines the Emitter terminal this
time pointing inwards in the transistor symbol.
Also,
all the polarities for a PNP transistor are reversed which means that it “sinks”
current into its Base as opposed to the NPN Transistor which
“sources” current through its Base. The main difference between the two types
of transistors is that holes are the more important carriers for PNP
transistors, whereas electrons are the important carriers for NPN transistors.
Then,
PNP transistors use a small base current and a negative base voltage to control
a much larger emitter-collector current. In other words for a PNP transistor,
the Emitter is more positive with respect to the Base and also with respect to
the Collector.
The
construction of a “PNP transistor” consists of two P-type semiconductor
materials either side of an N-type material as shown below.
A PNP Transistor Configuration
(Note:
Arrow defines the emitter and conventional current flow, “in” for a PNP
transistor.)
The
construction and terminal voltages for an NPN transistor are shown above. The PNP
Transistorhas very similar characteristics to their NPN bipolar
cousins, except that the polarities (or biasing) of the current and voltage
directions are reversed for any one of the possible three configurations looked
at in the first tutorial, Common Base, Common Emitter and Common Collector.
PNP Transistor Connection
The
voltage between the Base and Emitter ( VBE ), is now negative at the Base and positive
at the Emitter because for a PNP transistor, the Base terminal is always biased
negative with respect to the Emitter.
Also
the Emitter supply voltage is positive with respect to the Collector ( VCE ). So
for a PNP transistor to conduct the Emitter is always more positive with
respect to both the Base and the Collector.
The
voltage sources are connected to a PNP transistor are as shown. This time the
Emitter is connected to the supply voltage VCC with the load resistor, RL which limits the maximum current flowing
through the device connected to the Collector terminal. The Base voltage VB which
is biased negative with respect to the Emitter and is connected to the Base
resistor RB, which again is used to limit the maximum
Base current.
To
cause the Base current to flow in a PNP transistor the Base needs to be more
negative than the Emitter (current must leave the base) by approx 0.7 volts for
a silicon device or 0.3 volts for a germanium device with the formulas used to
calculate the Base resistor, Base current or Collector current are the same as
those used for an equivalent NPN transistor and is given as.
We can
see that the fundamental differences between a NPN Transistor and a PNP
Transistor is the proper biasing of the transistors junctions as the current
directions and voltage polarities are always opposite to each other. So for the
circuit above: Ic = Ie – Ib as
current must leave the Base.
Generally,
the PNP transistor can replace NPN transistors in most electronic circuits, the
only difference is the polarities of the voltages, and the directions of the
current flow. PNP transistors can also be used as switching devices and an
example of a PNP transistor switch is shown below.
A PNP Transistor Circuit
The Output Characteristics Curves for a PNP transistor look very similar
to those for an equivalent NPN transistor except that they are rotated by 180o to take account of the reverse polarity
voltages and currents, (the currents flowing out of the Base and Collector in a
PNP transistor are negative). The same dynamic load line can be drawn onto the
I-V curves to find the PNP transistors operating points.
Transistor Matching
Complementary Transistors
You may
think what is the point of having a PNP Transistor, when
there are plenty of NPN Transistors available that can be used as an amplifier or
solid-state switch?. Well, having two different types of transistors “PNP” and
“NPN”, can be a great advantage when designing power amplifier circuits such as
theClass B
Amplifier.
Class-B
amplifiers uses “Complementary” or “Matched Pair” (that is one PNP and one NPN
connected together) transistors in its output stage or in reversible H-Bridge motor control circuits were we want to
control the flow of current evenly through the motor in both directions.
A pair
of corresponding NPN and PNP transistors with near identical characteristics to
each other are calledComplementary
Transistors for
example, a TIP3055 (NPN transistor) and the TIP2955 (PNP transistor) are good
examples of complementary or matched pair silicon power transistors. They both
have a DC current gain, Beta, ( Ic/Ib )
matched to within 10% and high Collector current of about 15A making them ideal
for general motor control or robotic applications.
Also,
class B amplifiers use complementary NPN and PNP in their power output stage
design. The NPN transistor conducts for only the positive half of the signal
while the PNP transistor conducts for negative half of the signal.
This
allows the amplifier to drive the required power through the load loudspeaker
in both directions at the stated nominal impedance and power resulting in an
output current which is likely to be in the order of several amps shared evenly
between the two complementary transistors.
Identifying the PNP Transistor
We saw
in the first tutorial of this transistors section, that transistors are
basically made up of twoDiodes connected together back-to-back.
We can
use this analogy to determine whether a transistor is of the PNP type or NPN
type by testing its Resistance between
the three different leads, Emitter, Base and Collector. By
testing each pair of transistor leads in both directions with a multimeter will
result in six tests in total with the expected resistance values in Ohm’s given
below.
·
1. Emitter-Base Terminals – The Emitter to Base should act like a
normal diode and conduct one way only.
·
2. Collector-Base
Terminals – The
Collector-Base junction should act like a normal diode and conduct one way
only.
·
3. Emitter-Collector
Terminals – The
Emitter-Collector should not conduct in either direction.
Transistor Resistance Values for a PNP
Transistor and a NPN Transistor
Between Transistor
Terminals
|
PNP
|
NPN
|
|
Collector
|
Emitter
|
RHIGH
|
RHIGH
|
Collector
|
Base
|
RLOW
|
RHIGH
|
Emitter
|
Collector
|
RHIGH
|
RHIGH
|
Emitter
|
Base
|
RLOW
|
RHIGH
|
Base
|
Collector
|
RHIGH
|
RLOW
|
Base
|
Emitter
|
RHIGH
|
RLOW
|
Then we
can define a PNP Transistor as being normally “OFF” but a small
output current and negative voltage at its Base ( B )
relative to its Emitter ( E )
will turn it “ON” allowing a much large Emitter-Collector current to flow. PNP
transistors conduct when Ve is much
greater than Vc.
In
other words, a Bipolar PNP Transistor will ONLY conduct if both the Base and
Collector terminals are negative with respect to the Emitter
In the
next tutorial about Bipolar Transistors instead of using the transistor as an
amplifying device, we will look at the operation of the transistor in its
saturation and cut-off regions when used as a solid-state switch. Bipolar
transistor switches are used in many applications to switch a DC current “ON”
or “OFF”, from LED’s which require only a few milliamps of switching current at
low DC voltages, or motors and relays which may require higher currents at
higher voltages.
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