Title:The Transistor as a Switch
Operating Regions
1. Cut-off Region
Cut-off Characteristics
2. Saturation Region
Saturation Characteristics
Basic NPN Transistor Switching Circuit
Transistor As A Switch Example No1
Transistor As A Switch Example No2
Digital Logic Transistor Switch
PNP Transistor Switch
PNP Transistor Switching Circuit
Darlington Transistor Switch
Darlington Transistor Configurations
Transistor as a Switch Summary
When
used as an AC signal amplifier, the transistors Base biasing voltage is applied
in such a way that it always operates within its “active” region, that is the
linear part of the output characteristics curves are used. However, both the
NPN & PNP type bipolar transistors can be made to operate as “ON/OFF” type
solid state switches by biasing the transistors base differently to that of a
signal amplifier.
Solid
state switches are one of the main applications for the use of transistors, and transistor
switches can be
used for controlling high power devices such as motors, solenoids or lamps, but
they can also used in digital electronics and logic gate circuits.
If the
circuit uses the Bipolar Transistor as a Switch,
then the biasing of the transistor, either NPN or PNP is arranged to operate
the transistor at both sides of the “ I-V ” characteristics curves we
have seen previously.
The
areas of operation for a Transistor Switch are
known as the Saturation Region and the Cut-off
Region. This means then that we can ignore the operating
Q-point biasing and voltage divider circuitry required for amplification, and
use the transistor as a switch by driving it back and forth between its
“fully-OFF” (cut-off) and “fully-ON” (saturation) regions as shown below.
Operating Regions
The
pink shaded area at the bottom of the curves represents the “Cut-off” region
while the blue area to the left represents the “Saturation” region of the
transistor. Both these transistor regions are defined as:
1. Cut-off Region
Here
the operating conditions of the transistor are zero input base current ( IB ), zero
output collector current ( IC ) and maximum collector voltage ( VCE ) which
results in a large depletion layer and no current flowing through the device.
Therefore the transistor is switched “Fully-OFF”.
Cut-off Characteristics
|
·
• The input and Base are grounded (
0v )
·
• Base-Emitter voltage VBE < 0.7v
·
• Base-Emitter junction is reverse
biased
·
• Base-Collector junction is reverse
biased
·
• Transistor is “fully-OFF” (
Cut-off region )
·
• No Collector current flows ( IC = 0 )
·
• VOUT = VCE = VCC = ”1″
·
• Transistor operates as an “open
switch”
|
Then we
can define the “cut-off region” or “OFF mode” when using a bipolar transistor
as a switch as being, both junctions reverse biased, VB < 0.7v and IC = 0. For a PNP transistor, the
Emitter potential must be negative with respect to the Base.
2. Saturation Region
Here
the transistor will be biased so that the maximum amount of base current is
applied, resulting in maximum collector current resulting in the minimum
collector emitter voltage drop which results in the depletion layer being as
small as possible and maximum current flowing through the transistor. Therefore
the transistor is switched “Fully-ON”.
Saturation Characteristics
|
·
• The input and Base are connected
to VCC
·
• Base-Emitter voltage VBE > 0.7v
·
• Base-Emitter junction is forward
biased
·
• Base-Collector junction is forward
biased
·
• Transistor is “fully-ON” (
saturation region )
·
• Max Collector current flows ( IC = Vcc/RL )
·
• VCE = 0 ( ideal saturation )
·
• VOUT = VCE = ”0″
·
• Transistor operates as a “closed
switch”
|
Then we
can define the “saturation region” or “ON mode” when using a bipolar transistor
as a switch as being, both junctions forward biased, VB > 0.7v and IC = Maximum. For a PNP transistor, the
Emitter potential must be positive with respect to the Base.
Then
the transistor operates as a “single-pole single-throw” (SPST) solid state
switch. With a zero signal applied to the Base of the transistor it turns “OFF”
acting like an open switch and zero collector current flows. With a positive
signal applied to the Base of the transistor it turns “ON” acting like a closed
switch and maximum circuit current flows through the device.
An
example of an NPN Transistor as a switch being used to operate a relay is given
below. With inductive loads such as relays or solenoids a flywheel diode is
placed across the load to dissipate the back EMF generated by the inductive
load when the transistor switches “OFF” and so protect the transistor from
damage. If the load is of a very high current or voltage nature, such as
motors, heaters etc, then the load current can be controlled via a suitable
relay as shown.
Basic NPN Transistor Switching Circuit
The
circuit resembles that of the Common Emitter circuit we looked at in the previous
tutorials. The difference this time is that to operate the transistor as a
switch the transistor needs to be turned either fully “OFF” (cut-off) or fully
“ON” (saturated). An ideal transistor switch would have infinite circuit
resistance between the Collector and Emitter when turned “fully-OFF” resulting
in zero current flowing through it and zero resistance between the Collector
and Emitter when turned “fully-ON”, resulting in maximum current flow.
In
practice when the transistor is turned “OFF”, small leakage currents flow
through the transistor and when fully “ON” the device has a low resistance
value causing a small saturation voltage ( VCE ) across it. Even though the
transistor is not a perfect switch, in both the cut-off and saturation regions
the power dissipated by the transistor is at its minimum.
In
order for the Base current to flow, the Base input terminal must be made more
positive than the Emitter by increasing it above the 0.7 volts needed for a
silicon device. By varying this Base-Emitter voltage VBE, the Base current is also altered and
which in turn controls the amount of Collector current flowing through the
transistor as previously discussed.
When
maximum Collector current flows the transistor is said to be Saturated. The value of the
Base resistor determines how much input voltage is required and corresponding
Base current to switch the transistor fully “ON”.
Transistor As A Switch Example No1
Using
the transistor values from the previous tutorials of: β = 200, Ic = 4mA and Ib = 20uA, find the value of the Base resistor (Rb) required to switch the load fully “ON” when the input terminal
voltage exceeds 2.5v.
The
next lowest preferred value is: 82kΩ, this guarantees the transistor switch is
always saturated.
Transistor As A Switch Example No2
Again using
the same values, find the minimum Base current required to turn the transistor
“fully-ON” (saturated) for a load that requires 200mA of current when the input voltage is
increased to 5.0V. Also calculate the new value of Rb.
transistor Base current:
transistor Base
resistance:
Transistor
switches are used for a wide variety of applications such as interfacing large
current or high voltage devices like motors, relays or lamps to low voltage
digital logic IC’s or gates like AND gates
orOR gates. Here,
the output from a digital logic gate is only +5v but the device to be
controlled may require a 12 or even 24 volts supply. Or the load such as a DC
Motor may need to have its speed controlled using a series of pulses (Pulse
Width Modulation). transistor switches will allow us to do this faster and more
easily than with conventional mechanical switches.
Digital Logic Transistor Switch
The
base resistor, Rb is
required to limit the output current from the logic gate.
PNP Transistor Switch
We can
also use the PNP Transistors as a switch, the difference this time is that the
load is connected to ground (0v) and the PNP transistor switches the power to
it. To turn the PNP transistor operating as a switch “ON”, the Base terminal is
connected to ground or zero volts (LOW) as shown.
PNP Transistor Switching Circuit
The
equations for calculating the Base resistance, Collector current and voltages
are exactly the same as for the previous NPN transistor switch. The difference
this time is that we are switching power with a PNP transistor (sourcing
current) instead of switching ground with an NPN transistor (sinking current).
Darlington Transistor Switch
Sometimes
the DC current gain of the bipolar transistor is too low to directly switch the
load current or voltage, so multiple switching transistors are used. Here, one
small input transistor is used to switch “ON” or “OFF” a much larger current
handling output transistor. To maximise the signal gain, the two transistors
are connected in a “Complementary Gain Compounding Configuration” or what is
more commonly called a “Darlington Configuration” were the amplification
factor is the product of the two individual transistors.
Darlington
Transistors simply
contain two individual bipolar NPN or PNP type transistors connected together
so that the current gain of the first transistor is multiplied with that of the
current gain of the second transistor to produce a device which acts like a
single transistor with a very high current gain for a much smaller Base current.
The overall current gain Beta (β) or Hfe value of a Darlington device is the product
of the two individual gains of the transistors and is given as:
So
Darlington Transistors with very high β values
and high Collector currents are possible compared to a single transistor
switch. For example, if the first input transistor has a current gain of 100
and the second switching transistor has a current gain of 50 then the total
current gain will be 100 x 50 = 5000. An example of the two
basic types of Darlington transistor are given below.
Darlington Transistor Configurations
The
above NPN Darlington transistor switch configuration shows the Collectors of
the two transistors connected together with the Emitter of the first transistor
connected to the Base terminal of the second transistor therefore, the Emitter
current of the first transistor becomes the Base current of the second
transistor switching it “ON”.
The
first or “input” transistor receives the input signal to its Base. This
transistor amplifies it in the usual way and uses it to drive the second larger
“output” transistors. The second transistor amplifies the signal again
resulting in a very high current gain. One of the main characteristics of Darlington
Transistors is
their high current gains compared to single bipolar transistors.
As well
as its high increased current and voltage switching capabilities, another
advantage of a “Darlington Transistor Switch” is in its high switching speeds
making them ideal for use in inverter circuits, lighting circuits and DC motor
or stepper motor control applications.
One
difference to consider when using Darlington transistors over the conventional
single bipolar types when using the transistor as a switch is that the
Base-Emitter input voltage ( VBE ) needs to be higher at approx 1.4v for
silicon devices, due to the series connection of the two PN junctions.
Transistor as a Switch Summary
Then to
summarise when using a Transistor as a Switch the following conditions apply:
·
Transistor switches can be used to switch and control lamps,
relays or even motors.
·
When using the bipolar transistor as a switch they must be
either “fully-OFF” or “fully-ON”.
·
Transistors that are fully “ON” are said to be in their Saturation region.
·
Transistors that are fully “OFF” are said to be in their Cut-off region.
·
When using the transistor as a switch, a small Base current
controls a much larger Collector load current.
·
When using transistors to switch inductive loads such as relays
and solenoids, a “Flywheel Diode” is used.
·
When large currents or voltages need to be controlled, Darlington Transistors can be used.
In the
next tutorial about Transistors, we will
look at the operation of the junction field effect transistor known commonly as
an JFET. We
will also plot the output characteristics curves commonly associated with JFET
amplifier circuits as a function of Source voltage to Gate voltage.
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