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Transcript
The Zener Diode
The zener diode exhibits a constant voltage
drop when sufficiently reversed-biased.
This property allows the use of the zener
diode as a simple voltage regulator.
+IF
zener
point
-6
-3
+VF
1
+V
2
3
Constant
breakdown
voltage
R
Vr
D
Kit Building Class Lesson 3
Here, Vr will be equal to the reverse breakdown voltage of
the zener diode and should be constant. What is the purpose
of the resistor in this circuit? Its job is to limit the current
flowing through the zener diode:
V  Vr
I
R
Page 1
The Bipolar Junction Transistor
The transistor is a versatile device usually configured to perform as a switch or
as an amplifier. The bipolar junction transistor (BJT) is the most common type
and has three leads:
3
Base
3
Collector
2
Base
1
Emitter
PNP Transistor
Collector
2
1
Emitter
NPN Transistor
In a transistor, the flow of current from the collector to the emitter is controlled
by the amount of current flowing into the base of the transistor. If no current
flows into the base, no current will flow from the collector to the emitter (it acts
like an open switch). If current flows into the base, then a proportional amount
of current flows from the collector to the emitter (somewhat like a closed switch).
Kit Building Class Lesson 3
Page 2
The NPN Transistor
Rb
+
c
Rb
b
+
c
b
IC
+
e
e
-
Re
No current flows from base to emitter, so
the transistor acts like an open switch and
no current flows from collector to emitter.
(Note: current never flows from base to
collector or vice versa, regardless of the
base current.)
+
-
IB
Re
Current now flows through the transistor from
base to emitter. This causes the transistor to
allow current to flow from the collector to the
emitter. The size of the collector current
depends on the size of the base current and
the beta b of the transistor:
b  IC I B
A typical transistor has a beta of about 100.
Kit Building Class Lesson 3
Page 3
Base and Collector Currents
What’s the base current IB? Use
Kirchhoff’s voltage law:
c
RB
b
IC
E  I B RB  I B RE  0.7V
Now find the collector current IC:
IC  b  I B
Kit Building Class Lesson 3
E
e
E  I B ( RB  RE )  0.7V
E  0.7V
IB 
RB  RE
+
-
0.7 volts is lost at the
junction of the base
and emitter
IB
RE
What’s the maximum value for the
collector current?
E
IC 
RE
Page 4
The PNP Transistor
c
b
Ib
Ic
-
Rb
e
+
Re
The PNP transistor behaves identically to the NPN transistor, except that all
polarities are reversed. The voltages are applied with opposite polarity, and
the currents run opposite to those in the NPN transistor, but all other behaviors
are the same.
Kit Building Class Lesson 3
Page 5