THYRISTOR REVIEW QUIZ

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Thyristors

Thyristors are a class of semiconductor devices characterized
by 4-layers of alternating p and n material. Four-layer devices
act as either open or closed switches; for this reason, they are
most frequently used in control applications.

Some thyristors and their symbols are

(c) Diac

(d) Triac

(a)

(e) SCS

(b) SCR

4-layer diode

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Electronic Devices, 9th edition
Thomas L. Floyd

The Four-Layer Diode

The 4-layer diode (or Shockley diode) is a type of thyristor
that acts something like an ordinary diode but conducts in
the forward direction only after a certain anode to cathode
voltage called the forward-breakover voltage is reached.

The basic construction of a 4-layer diode and its schematic
symbol are shown

The 4-layer diode has two leads,
labeled the anode (A) and the
cathode (K).

The symbol reminds you that it acts
like a diode. It does not conduct
when it is reverse-biased.

p

n

p

n

1

2

3

Anode (A)

Cathode (K)

A

K

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Electronic Devices, 9th edition
Thomas L. Floyd

The concept of 4-layer devices is usually
shown as an equivalent circuit of a pnp
and an npn transistor.

Ideally, these devices would not
conduct, but when forward biased, if
there is sufficient leakage current in the
upper pnp device, it can act as base
current to the lower npn device causing
it to conduct and bringing both
transistors into saturation.

The Four-Layer Diode

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The unusual connection shown uses positive
feedback. Any change in the base current of
Q2 is amplified and fed back through Q1 to
magnify the original change. This positive
feedback continues changing the base current
of Q2 until both transistors go into either
saturation or cutoff.

The Four-Layer Diode

The only way to turn on the device is by breakover. This
means using a large enough supply voltage to break down the
Q1 collector diode. Since the collector current of Q1 increases
the base current of Q2, the positive feedback will start.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The characteristic curve for a 4-layer diode shows the
forward blocking region. When the anode-to-cathode
voltage exceeds VBR, conduction occurs. The switching
current at this point is IS.

On

Off

VBR(F)
VAK

IH

0

IA

IS

Forward-
conduction
region

Forward-
blocking
region

Once conduction begins,
it will continue until
anode current is reduced
to less than the holding
current (IH). This is the
only way to stop
conduction.

The Four-Layer Diode

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The circuit shown is a relaxation oscillator. When the switch
is closed, the capacitor charges through R until its voltage
reaches the forward breakover voltage of the 4-layer diode.
At this point the diode switches into conduction, and the
capacitor rapidly discharges through the diode. Discharging
continues until the current through the diode falls below the
holding value. At this point, the diode switches back to the
off state, and the capacitor begins to charge again.

Four-Layer Diode Application

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Silicon-Controlled Rectifier (SCR)

The SCR had its roots in the 4-layer diode. By adding a
gate connection, the SCR could be triggered into
conduction. The SCR is the most widely used thyristor. It
can switch very large currents on and off.

The SCR can be turned on by exceeding the forward
breakover voltage or by gate current. The gate current
controls the amount of forward breakover voltage required
for turning it on.

The SCR is far more useful
than a four-layer diode
because the gate triggering is
easier than breakover
triggering

VF

IR

VR

IA

IH0

IH1
IH2

IG2 > IG1IG1 > IG0
IG0 = 0

VBR(F0)
VBR(F1)
VBR(F 2)
0

A

K

G

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Like the 4-layer diode, the SCR will conduct as
long as forward current exceeds IH. There are two
ways to drop the SCR out of conduction:

1) Anode current interruption

2) Forced commutation.

Anode current can be interrupted by breaking
the anode current path, providing a path around
the SCR, or dropping the anode voltage to the
point that IA < IH.

RA

G

IA = 0

+V

Silicon-Controlled Rectifier (SCR)

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Force commutation uses an external circuit to momentarily
force current in the opposite direction to forward conduction
The basic circuit consists of a switch and a capacitor. While
the SCR is conducting, the switch is open and Cc is charged
to the supply voltage through Rc .
To turn off the SCR, the switch
is closed, placing the capacitor
across the SCR and forcing
current through it opposite to
the forward current.

SCRs are commonly used in ac
circuits, which forces the SCR
out of conduction when the ac
reverses.

Silicon-Controlled Rectifier (SCR)

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Electronic Devices, 9th edition
Thomas L. Floyd

SCR Specifications

Forward-breakover voltage, VBR(F):
This is the voltage at which the SCR
enters the forward-conduction region.

Holding current, IH: This is the value of
anode current below which the SCR
switches from the forward-conduction
region to the forward-blocking region.

Gate trigger current, IGT: This is the
value of gate current necessary to switch
the SCR from the forward-blocking
region to the forward-conduction region
under specified conditions.

Forward-
conduction
region (on)

for IG = 0

VF

VBR(F)

Forward-
blocking
region (off)

IR

Reverse-
blocking
region

0

Reverse-
avalanche
region

VBR(R)

VR

IH

IF

Characteristic
for IG = 0

Three important SCR specifications are:

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

SCR Applications

The figure shows an SCR circuit that permits current to be
switched to a load by the momentary closure of switch
SW1 and removed from the load by the momentary
closure of switch SW2.

Closure of SW1 provides a
pulse of current into the gate,
thus triggering the SCR on.
When SW2 is momentarily
closed, current is shunted
around the SCR, thus reducing
its anode current below the
holding value. This turns the
SCR off.

On-Off Control of Current

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Electronic Devices, 9th edition
Thomas L. Floyd

Example

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Electronic Devices, 9th edition
Thomas L. Floyd

A common application of SCRs is in the control of ac power
for lamp dimmers, electric heaters, and electric motors. A
half-wave, variable-resistance, phase-control circuit is
shown. RL represents the resistance of the load, R1 limits the
current, and potentiometer R2 sets the trigger level for the
SCR.

By adjusting R2, the SCR
can be made to trigger at
any point on the positive
half-cycle of the ac
waveform between 0°
and 90°, as shown in
figure

Half-Wave Power Control

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Electronic Devices, 9th edition
Thomas L. Floyd

Half-Wave Power Control

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Example

When there is load current, the SCR is
conducting and the voltage across it is
ideally zero. When there is no load
current, the voltage across the SCR is
the same as the applied voltage. The
waveforms are shown.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The circuit shown will maintain lighting by using a backup
battery when there is an ac power failure. As long as the ac
power is available, the battery charges through diode D3 and
R1. When there is an interruption of ac power, the SCR
conducts and current from the battery keeps illumination

Backup Lighting for Power Interruptions

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

An over-voltage protection (crowbar) circuit is shown. If the
dc output voltage is exceeds the zener voltage, the zener
conducts and the voltage divider produces an SCR trigger
voltage. The trigger voltage turns on the SCR, causing the
fuse to blow.

An Over-Voltage Protection Circuit

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Electronic Devices, 9th edition
Thomas L. Floyd

 The SCR can be used in conjunction with an RC circuit to
produce a repetitive sawtooth waveform.

 The time constant is set by R1 and C1, and the voltage at
which the SCR triggers on is determined by the variable
voltage-divider formed by R2 and R3 .

 When the switch is closed, the capacitor begins charging
and turns on the SCR. When the SCR turns on, the
capacitor quickly discharges through it; the anode current
then decreases below the holding value, causing the SCR
to turn off.

 As soon as the SCR is off, the capacitor starts charging
again and the cycle is repeated.

Sawtooth Generator

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Electronic Devices, 9th edition
Thomas L. Floyd

Sawtooth Generator

By adjusting the potentiometer, the frequency of the sawtooth
waveform can be changed.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The Diac

The diac is a thyristor that acts like two back-to-back 4-
layer diodes. It can conduct current in either direction.
Because it is bidirectional, the terminals are equivalent and
labeled A1 and A2.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

The Diac

 The top and bottom layers contain both n and p materials.

 The right side of the stack can be regarded as a pnpn
structure with the same characteristics as a four-layer
diode, while the left side is an inverted four-layer diode
having an npnp structure.

 Conduction occurs in a diac when the breakover voltage is
reached with either polarity across the two terminals.

 Once breakover occurs, current is in a direction depending
on the polarity of the voltage acrossthe terminals.

 The diac remains in conduction as long as the current is
above the holding current, IH.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The Triac

Basically, a triac can be thought as two SCRs connected in
parallel and in opposite directions with a common gate
terminal. Unlike the SCR, the triac can conduct current in
either direction when it is triggered on, depending on the
polarity of the voltage across its A1 and A2 terminals.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

TheTriac

 The characteristic curve shows that the breakover potential
decreases as the gate current increases, just as with the
SCR.

 When the voltage on the A1 terminal is positive with
respect to A2, a gate current pulse will cause the left SCR
to conduct. When the anode voltages are reversed, the gate
current pulse will cause the right SCR to conduct.

 As with other thyristors, the triac ceases to conduct when
the anode current drops below the specified value of the
holding current IH.

 The only way to turn off the triac is to reduce the current to
a sufficiently low level.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Triac Applications

Like the SCR, triacs are also used to control average power to a
load by the method of phase control. The triac can be triggered
such that the ac power is supplied to the load for a controlled
portion of each half-cycle.

Vin

RL

VG

A1

G

A2

IL

Triac on

Delay
angle
Conduction
angle

During +ve half-cycle,
the triac is off for a
certain interval, called
the delay angle, and
then it is on for the
remaining portion,
called the conduction
angle. Similar action
occurs on the negative
half-cycle.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Triac Applications

One example of phase control using a triac is shown. Diodes
are used to provide trigger pulses to the gate of the triac. Diode
D1 conducts during the positive half-cycle and Diode D2
conducts during the negative half-cycle. The value of R1 sets
the point at which the triac triggers.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The Silicon-Controlled Switch (SCS)

The silicon-controlled switch (SCS) is similar in construction
to the SCR. The SCS, however, has two gate terminals, the
cathode gate and the anode gate. The SCS can be turned on
and off using either gate terminal.

Cathode
gate
(GK)

Cathode (K)

Anode (A)
Anode
gate
(GA)

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Electronic Devices, 9th edition
Thomas L. Floyd

The Silicon-Controlled Switch (SCS)

The SCS can also be turned on by applying a positive pulse on
the cathode gate or a negative pulse on the anode gate. To turn
the SCS off, a negative pulse is applied to the cathode gate or a
positive pulse is applied to the anode gate.

The SCS and SCR are used in similar applications. The SCS
has the advantage of faster turn-off with pulses on either gate
terminal.

In this example, the SCS is controlling
a dc source. The load is in the cathode
circuit, which has the advantage of
one side of the load being on circuit
ground.
RL

V

V

V

GK

GA

L

A

GK

GA

K

+VCC

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The Unijunction Transistor (UJT)

The UJT (unijunction transistor) is a three-terminal device. It
is composed of a bar of N-type silicon with a P-type
connection in the middle. The connections at the ends of the
bar are known as bases B1 and B2; the P-type mid-point is the
emitter.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

The Unijunction Transistor (UJT)

The equivalent circuit for the UJT is shown. The total
resistance between the base terminals is the sum of the
dynamic resistances 𝑟𝑟′𝐵𝐵1 and 𝑟𝑟′𝐵𝐵2 and is called the interbase
resistance 𝑟𝑟′𝐵𝐵𝐵𝐵. The ratio η = 𝑟𝑟′𝐵𝐵1/𝑟𝑟′𝐵𝐵𝐵𝐵 is called a UJT
standoff ratio. When the emitter voltage reaches VP (the peak
point), the UJT “fires”, where𝑉𝑉𝑃𝑃 = η𝑉𝑉𝐵𝐵𝐵𝐵 + 𝑉𝑉𝑃𝑃𝑛𝑛

–

r′B2

r′B1

E

B2

B1

+
VEB1

+–
Vpn

–

+

VBB

ηVBB

IE

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Electronic Devices, 9th edition
Thomas L. Floyd

The Unijunction Transistor (UJT)

Where 𝑉𝑉𝑃𝑃𝑛𝑛 is the barrier potential of the pn Junction. After
turn-on, the UJT operates in a negative resistance region up to
a certain value of IE (valley point). Beyond the valley point,
the device is in saturation, and VE increases very little with an
increasing IE .

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

UJT Applications

The UJT can be used as a trigger device for SCRs and triacs.
Other applications include nonsinusoidal oscillators, sawtooth
generators, phase control, and timing circuits. The figure
shows a UJT relaxation oscillator as an example of one
application.

When dc power is applied, the capacitor C
charges until it reaches the peak-point
voltage. At this point, the pn junction
becomes forward-biased, and the emitter
characteristic goes into the negative
resistance region. The capacitor quickly
discharges through the forward-biased
junction.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

UJT Applications

When the capacitor voltage decreases to the valley-point
voltage the UJT turns off, the capacitor begins to charge again,
and the cycle is repeated. During the discharge time of the
capacitor, the UJT is conducting.

to ensure that the UJT
reliably turn on and turn off
R1 must be in the range

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Electronic Devices, 9th edition
Thomas L. Floyd

Example

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Electronic Devices, 9th edition
Thomas L. Floyd

A circuit using a UJT to fire an SCR is shown. When the
UJT fires, a pulse of current is delivered to the gate of the
SCR. The setting of R1 determines when the UJT fires. The
diode isolates the UJT from the negative part of the ac.

R1

VE

R2

C

B

A
R

R

L

G

D

UJT

SCR

The UJT produces a
fast, reliable current
pulse to the SCR, so
that it tends to fire in
the same place every
cycle.

UJT Applications

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Electronic Devices, 9th edition
Thomas L. Floyd

The Programmable Unijunction Transistor (PUT)

The PUT is a 4-layer thyristor with a gate. The gate pulse can
trigger a sharp increase in current at the output. The cathode
terminal is connected to a voltage lower than the gate. When
the anode voltage becomes 0.7 V higher than the gate, the
PUT turns on. The device will remain on until its anode
current falls below a valley current.

VAK (anode-to-cathode voltage)

VP

VV

IP

IV
0

IA
(anode current)

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Electronic Devices, 9th edition
Thomas L. Floyd

The Programmable Unijunction Transistor (PUT)

The principle application for a PUT is for driving SCRs and
triacs, but, like the UJT, can be used in relaxation oscillators.
The gate is biased at +9 V. When dc power is applied, the PUT
is off and the capacitor charges toward +18 V. When the
capacitor reaches VG+0.7 V, the PUT turns on and the capacitor
rapidly discharges through the low on resistance of the PUT

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Selected Key Terms

4-layer diode

Thyristor

SCR

The type of 2-terminal thyristor that conducts
current when the anode-to-cathode voltage reaches
a specified “breakover” value.

A class of four-layer (pnpn) semiconductor
devices.

Silicon-controlled rectifier; a type of three
terminal thyristor that conducts current when
triggered by a voltage at the single gate terminal
and remains on until anode current falls below a
specified value.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Selected Key Terms

LASCR

Diac

Triac

Light-activated silicon-controlled rectifier; a four
layer semiconductor device (thyristor) that
conducts current in one direction when activated
by a sufficient amount of light and continues to
conduct until the current falls below a specified
value.

A two-terminal four-layer semiconductor device
(thyristor) that can conduct current in either
direction when properly activated.

A three-terminal thyristor that can conduct current
in either direction when properly activated.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Selected Key Terms

SCS

UJT

PUT

Silicon-controlled switch; a type of four-terminal
thyristor that has two gate terminals that are used
to trigger the device on and off.

Unijunction transistor; a three terminal single pn
junction device that exhibits a negative resistance
characteristic.

Programmable unijunction transistor; a type of
three terminal thyristor (physically more like an
SCR than a unijunction) that is triggered into
conduction when the voltage at the anode exceeds
the voltage at the gate.

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
All rights reserved.
Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

1. The 4-layer (Shockley) diode can conduct current if

a. the anode-to-cathode voltage exceeds VBR

b. a current pulse is applied to the gate

c. both a and b are correct

d. none of the above

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

2. The SCR can conduct current if

a. the anode-to-cathode voltage exceeds VBR

b. a current pulse is applied to the gate

c. both a and b are correct

d. none of the above

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

3. A bidirectional thyristor is the

a. 4-layer diode

b. SCR

c. triac

d. silicon-controlled switch

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

4. A thyristor that looks like two back-to-back 4-layer
diodes is the

a. SCR

b. triac

c. SCS

d. diac

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

5. An SCR turns off when the

a. gate trigger current drops below a specified level

b. anode current drops below the holding current

c. both a and b are true

d. none of the above

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

6. The purpose of a crowbar circuit is to protect a load from

a. excessive ripple

b. low-voltage

c. over-voltage

d. all of the above

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

7. A diac and triac are similar in that both devices

a. can use breakover triggering

b. can be used in ac circuits

c. are bidirectional

d. all of the above

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

8. A device that has an unstable negative resistance region
is the

a. UJT

b. diac

c. triac

d. SCS

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

9. The symbol for a silicon-controlled switch (SCS) is

(a) (b) (c) (d)

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

10. A programmable unijunction transistor (PUT) is
“programmed” by choosing the

a. RC time constant

b. gate resistors

c. power supply voltage

d. cathode resistor

© 2012 Pearson Education. Upper Saddle River, NJ, 07458.
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Electronic Devices, 9th edition
Thomas L. Floyd

Quiz

Answers:

1. a

2. c

3. c

4. d

5. b

6. c

7. d

8. a

9. d

10. b