As per Revised Syllabus of
Visvesvaraya Technological University
® Basic Electronics - at a Glance (One day Revision Book) Atul P. Godse M.S. Software Systems (BITS Pilani) B.E. Industrial Electronics Formerly Lecturer in Department of Electronics Engg. Vishwakarma Institute of Technology Pune
Uday A. Bakshi M.E. (Electrical) Formerly Lecturer in Department of Electronics Engg. Vishwakarma Institute of Technology Pune
®
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TT able of Contents Module - 1 Chapter - 1
Semiconductor Diodes and Applications
Chapter - 2
Bipolar Junction Transistor
®
(1 - 1) to (1 - 40 ) (2 - 1) to (2 - 22)
Module - 2 Chapter - 3
BJT Biasing
(3 - 1) to (3 - 16)
Chapter - 4
Introduction to Operational Amplifiers
(4 - 1) to (4 - 28)
Module - 3 Chapter - 5
(5 - 1) to (5 - 34)
Digital Electronics
Module - 4 Chapter - 6
Flip-Flops
(6 - 1) to (6 - 6)
Chapter - 7
Microprocessors and Microcontrollers
(7 - 1) to (7 - 26)
Chapter - 8
Transducers
(8 - 1) to (8 - 10)
Module - 5 Chapter - 9
(9 - 1) to (9 - 34)
Communication Systems
Chapter - 10 Telephone Systems and Optical Fibre Communication (10 - 1) to (10 - 8)
(ii)
Semiconductor Diodes and Applications
1
Chapter at a Glance 1.
Introduction to P-N Junction
The two types of materials namely n-type and p-type are chemically combined with a special fabrication technique to form a p-n junction. Such a semiconductor p-n junction forms a popular electronic device called diode. 2.
Theory of P-N Junction
There exists a wall near the junction with negative immobile charge on p side and positive immobile charge on n side. There are no charge carriers in this region. The region is depleted off the charge carriers hence called depletion region, depletion layer or space charge region.
3.
Material
Symbol
Value of barrier potential
Silicon
Si
0.6 V
Germanium
Ge
0.2 V
The P-N Junction Diode Direction of conventional current
Anode
Cathode p type
n type
Fig. 1.1 Symbol of a diode
4.
Reverse Biasing of Diode
If reverse voltage is increased beyond particular value, large reverse current can flow damaging the diode. This is called reverse breakdown of a diode. Such a reverse breakdown of a diode can take place due to the following two effects, 1. Avalanche effect and
2. Zener effect (1 - 1) TM
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5.
1-2
Semiconductor Diodes and Applications
V-I Characteristics of Diode
If(mA)
Normal operating region
Reverse breakdown voltage I 0 VBR VR Knee
Knee Vf
Vg Cut in voltage
I0 Reverse saturation current
Breakdown region
Forward characteristics
Reverse characteristics IR(mA)
Fig. 1.2 Complete V-I characteristics of a diode
6.
Diode Current Equation and Nature of Characteristics The diode current equation is,
[
]A
I = I 0 e V / hVT - 1 where
I0 = Reverse saturation current in amperes, h = 1 for germanium diode VT
V = Applied voltage
and = 2 for silicon diode
= Voltage equivalent of temperature in volts VT = kT volts VT = 8.62 ´ 10
–5
´ 300 = 0.02586 V » 26 mV
... At 27 ºC
For forward biased, V must be taken positive and we get current I positive which is forward current. For reverse biased, V must be taken negative and we get negative current I which indicates that it is reverse current. 7.
D.C. Equivalent Circuits of Diode
Sr. No. 1.
Diode approximation Ideal diode
Behaviour Rf = 0 W Rr = ¥ W Short in forward bias. TM
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D.C. Equivalent circuit If
Basic Electronics
2.
3.
1-3
Semiconductor Diodes and Applications
Diode with constant forward voltage drop
The forward voltage drop is constant and it behaves as d.c. battery of voltage Vf = Vg
Complete d.c. equivalent circuit
This assumes finite forward resistance which is its dynamic forward resistance r f in series with battery of voltage Vg .
Vf = V g + – If
+
Vg
–
rf
If
Ideal
Total diode drop is, Vf = Vg + If rf
8.
Rectifiers
A rectifier is a device which converts a.c. voltage to pulsating d.c. voltage, using one or more p-n junction diodes. 9. \
Ripple Factor Ripple factor
Ripple factor =
I ac = I DC
g=
R. M. S. value of a.c. component of output Average or d.c.component of output
I 2RMS - I 2DC I DC
2
æI ö = ç RMS ÷ - 1 I è DC ø
10. Transformer Utilization Factor (T.U.F.) \
T.U.F. =
D. C. Power delivered to the load A. C. Power rating of the transformer
11. Voltage Regulation %R=
(Vdc ) NL – (Vdc ) FL ´ 100 (Vdc ) FL
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…As per definition
Basic Electronics
1-4
Semiconductor Diodes and Applications
12. Comparison of Rectifier Circuits Circuit Diagrams Half Wave
Full Wave
iL
RL
iL
Bridge
RL RL iL
Sr. No.
Parameter
Half Wave
Full Wave
Bridge
1.
Number of diodes
1
2
4
2.
Average D.C. current ( IDC )
Im p
2I m p
2I m p
3.
Average D.C. voltage ( E DC )
E sm p
2E sm p
2E sm p
4.
RMS current ( IRMS )
Im 2
Im 2
Im 2
5.
D.C. power output (PDC )
I2m R L p2
4 p2
I2m R L
4 p2
I2m R L
6.
A.C. power input ( PAC )
I2m ( R L + R f + R s) 4
7.
Maximum rectifier efficiency ( h)
40.6 %
81.2 %
81.2 %
8.
Ripple factor ( g)
1.21
0.482
0.482
9.
Maximum load current ( I m )
E sm Rs + R f + RL
E sm Rs + R f + RL
E sm R s + 2R f + R L
10.
PIV rating of diode
Esm
2 Esm
Esm
11.
Ripple frequency
50 Hz
100 Hz
100 Hz
12.
T.U.F.
0.287
0.693
0.812
I2m ( R f + R s + R L) I2m ( 2R f + R s + R L) 2 2
13. Filter Circuits The filter is an electronic circuit composed of capacitor, inductor or combination of both and connected between the rectifier and the load so as to convert pulsating d.c. to pure d.c.
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Semiconductor Diodes and Applications
14. Approximate Analysis of Capacitor Filter Vr
Vr(rms) =
2 3
… As triangular
E DC = Peak to peak ripple voltage 2 f C RL
… For full wave
Ripple factor =
Vr (rms) 1 = E DC 4 3 f C RL
… For full wave
Ripple factor =
1 2 3 f C RL
… For half wave
Vr =
\
1 ù E DC = E sm - I DC é êë 4 fCúû
… For full wave
1 ù E DC = E sm - I DC é êë 2 fCúû
… For half wave
15. Expression for Ripple Voltage \
\
Vr(rms) =
Vr (rms) =
I DC 4 3f C I DC 2 3fC
volts
(For full wave)
... (a)
volts
(For half wave)
... (b)
16. Power Supply Performance SR = VHL – VLL % SR =
SR ´ 100 Vnom
where Vnom= Nominal load voltage
LR = VNL – VFL \
% LR =
VNL - VFL ´ 100 VFL
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Rout =
D Vout DI L
SV =
D Vout D Vin
ST =
D Vout DT
RR =
Semiconductor Diodes and Applications
Vin and temperature constant
I L and temperature constant
Vin and I L constant
VR(out) Ripple content in output = VR(in) Ripple content in input
17. Zener Diode as a Shunt Regulator R
+
IL
I
Vin Unregulated
Iz
D
+ V –Z
+ Vo
L O A D
RL
–
–
Fig. 1.3 Zener diode as a shunt regulator
R=
Vin - VZ I
i.e.
I=
Vin - VZ R
I = IZ + IL 18. Design of Zener Regulator Rmax =
Vinmin - VZ Vinmin - Vo = I Lmax + I Zmin I Lmax + I Zmin
… (1)
Rmin =
Vinmax - VZ V - Vo = inmax I Lmin + I Zmax I Lmin + I Zmax
… (2)
I Zmax =
PD P or = Z VZ VZ
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1-7
Semiconductor Diodes and Applications
19. Series Negative Clipper Circuit –
+ D
Input Vin
Load
RL
Vo
Fig. 1.4 Negative series clipper Vo
Vin
Vm
Vm
t
t p
0
p
0
2p
2p
Negative half is clipped off (a) Input voltage
(b) Output voltage
Fig. 1.5 Waveforms of series negative clipper
20. Series Positive Clipper Circuit –
+ D
Input Vin
Load
Vo Output
RL
Fig. 1.6 Positive series clipper Vin +Vm p
0 –Vm Vo
t
Positive is clipped off
p
0 –Vm Vo
Output
2p
t
t
2p
Positive is clipped off p
0
–Vm
Output
2p
t
–Vm Voltage across ideal diode D D OFF ON
Voltage across ideal diode D D OFF ON
VD
0 –Vm
Input
+Vm 2p
p
0
Vin
Input
p
VD t
2p
0 –Vm
(a) Sinusoidal input
p
2p
(b) Triangular input
Fig. 1.7 Waveforms of series positive clipper TM
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t
Basic Electronics
1-8
Semiconductor Diodes and Applications
21. Parallel Clipper with Positive Clipping R1 +
Vin
A
Input
– +
I
Input
D –
RL
D and RL in parallel
p
0 –Vm
Vo
Vo
D ON
D OFF p
0
t
2p
2p
t
–VmRL
Fig. 1.8 Parallel positive clipper
R1+RL
Positive half cycle of input clipped off
Fig. 1.9 Waveforms for parallel positive clipper
22. Parallel Clipper with Negative Clipping R1
Vin
A
Input Input
D
Vin
RL
Vo Output
p
0
Vo
Fig. 1.10 Basic parallel clipper
D (OFF)
2p
t
D (ON)
p
2p
t
Negative half cycle of input clipped-off
Fig. 1.11 Waveforms for parallel negative clipper
23. Clamper Circuits The circuits which are used to add a d.c. level as per the requirements to the a.c. output signal are called clamper circuits.
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1-9
Semiconductor Diodes and Applications
Important Theory Questions and Answers
Ø
What is a p-n junction ?
+
VTU : Aug.-01, Feb.-02, 04, Marks 3, Jan.-09, Marks 2
The two types of materials namely n-type and p-type are chemically combined with a special fabrication technique to form a p-n junction. Such a semiconductor p-n junction forms a popular electronic device called diode.
Ø
Describe the physical mechanism of avalanche and zener breakdown in a p-n junction diode. + VTU : Aug.-99, 2000, 02, 05, March-01, 02, 05, Marks 5, Aug.-04, Marks 4
Breakdown Due to the Avalanche Effect :
· If reverse voltage is increased, at a particular value, velocity of minority carriers increases. · Due to the kinetic energy more minority carriers are generated. The collision make the electrons to break the co-volent bonds. · These electrons are available as minority carriers. They again collide with another atoms to generate more minority carriers. This is called carrier multiplication. · Finally large number of minority carriers move across the junction, breaking the p-n junction. These minority carriers give rise to a very high reverse current. · This effect is called avalanche effect and the mechanism of destroying the junction is called reverse breakdown of a p-n junction. Breakdown Due to the Zener Effect : · When a p-n junction is heavily doped the depletion region is very narrow.
· Due to narrow depletion region and high reverse voltage, electric field is intense. · Such an intense field is enough to pull the electrons out of the valence bands of the stable atoms. Such a creation of free electrons is called zener effect. These minority carriers constitute very large current and mechanism is called zener breakdown.
Ø
Draw and explain the V-I characteristics of a p-n junction diode. + VTU : Aug.-99, 2000, 01, 04, 05, March-2000, 01, Jan.-02, 04, 09, 13, Marks 8
· In forward biasing Vf is the voltage across the p-n junction and If is the forward current. · The forward characteristics of a diode is shown in the Fig. 1.12. · Forward characteristics can be divided into two regions : 1. Region O to P : As long as Vf is less than cut-in voltage (Vg ) , the current flowing is very small. 2. Region P to Q and onwards : As Vf increases towards Vg the width of depletion region goes on reducing. When Vf exceeds Vg the depletion region becomes very thin TM
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1 - 10
Semiconductor Diodes and Applications If in mA
and current If increases suddenly. This increase in the current is exponential as shown in the Fig. 1.12 by the region P to Q.
· The point P, current starts called knee corresponding voltage.
after which the forward increasing exponentially is of the curve and the voltage is called knee
Q F
D DIf E
C Knee
· Forward characteristics is plotted in the first quadrant.
P
DVf
O
A
B
Vf
in volts · The reverse voltage across the diode is VR and reverse current through the diode is IR hence graph of IR against VR is called Fig. 1.12 Forward characteristics of a diode reverse V-I characteristics of p-n junction. Cut-in voltage (vg)
· Reverse characteristics are plotted in the third quadrant. · As the reverse voltage is increased, reverse current increases initially but after a small voltage becomes constant equal to reverse saturation current I0. This point is shown as P, in the Fig. 1.13.
Reverse breakdown voltage (VBR) O
– VR
A Sharp increase in current
Knee I0 remains point constant
I0 Reverse saturation current
P
– IR
Fig. 1.13 Reverse characteristics of p-n junction diode
· After this, though reverse voltage is increased, the reverse current remains constant till point A.
· At point A, reverse breakdown of the diode occurs and current increases sharply damaging the diode. This point is called knee of the reverse characteristics. · Reverse breakdown voltage of the p-n junction denoted as VBR. · The complete V-I characteristics of p-n junction diode is the combination of its forward as well as reverse characteristics. (Refer Fig. 1.2 on page 1-2)
Ø
Write the diode current equation of a p-n junction and explain the V-I characteristics from it. + VTU : Aug.-03, 05, Marks 8, Aug.-99, 2000, 01, March-2000, 01, Feb.-02, 04, Marks 5, Aug.-04, Marks 6, Jan.-09, Marks 8
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Semiconductor Diodes and Applications
The diode current equation is,
[
]A
I = I 0 e V / hVT - 1
V-I Characteristics from Equation of Diode :
· For a forward biased condition, the bias voltage V is considered positive and hence exponential index has positive sign. Due to this, 1 << e V / hVT hence neglecting 1 we get the equation for a forward current as, If = I0 e V / hVT
· Once bias voltage exceeds cut in voltage, the forward current increases exponentially. · In reverse biased condition, the bias voltage V is treated negative and due to this exponential index has negative sign. So e - V / hVT << 1, hence neglecting exponential term we get,
If
If = I0e
V/hV
T
Exponential forward current
Reverse breakdown voltage
0
–V
+V Reverse saturation current (I0)
I0
I » – I0 Breakdown region
IR
aI R @ I0 (–1) @ – I0 Fig. 1.14 V-I characteristics of p-n junction diode
· Under reverse biased condition, the current is reverse saturation current which is negative indicating that it flows in opposite direction to that of forward current and almost constant.
Ø
Draw the full wave rectifier circuit and explain its operation. + VTU : Aug.-07, 09, Jan.-13, Dec.-11, June-12, Marks 6 es=Esmsin wt
· The full wave rectifier conducts during both positive and negative half cycles of input a.c. supply. · The full wave rectifier circuit is shown in the Fig. 1.15. Operation of the Circuit : Consider the positive half cycle of ac input voltage in which terminal (A) is positive and terminal (B) negative due to center tap transformer.
D1
A
iL id1
+
EDC –
A. C. supply
es
Center tap transformer
B
id2 D2
Fig. 1.15 Full wave rectifier TM
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RL
Basic Electronics
1 - 12
· The diode D1 will be forward biased and hence will conduct; while diode D2 will be reverse biased and will act as an open circuit and will not conduct. The diode D1 supplies the load current, i.e. iL = id1 .
Semiconductor Diodes and Applications
A +
A.C.Supply
D1, ON
+
id1 Load voltage
iL
Load voltage RL
–
Load voltage – B
D2, OFF
· In the next half cycle of ac Fig. 1.16 Current flow during positive half cycle voltage, polarity reverses and terminal (A) becomes negative and (B) positive. The diode D2 conducts, being forward biased, while D1 does not, being reverse biased. The diode D2 supplies the load current, i.e. iL = id2 . Load voltage A _
D1, OFF
t RL
iL
A.C.Supply id2
+ B
D2, ON
Load current direction remains same
Fig. 1.17 Current flow during negative half cycle
Ø
Derive the expressions for the average d.c. current, d.c. load voltage, rectifier efficiency, ripple factor, PIV rating and ripple frequency for the full wave rectifier circuit with two diodes. + VTU : Feb.-01, 02, Aug.-01, 02, 03, 07, July-11, Marks 8
· Consider one cycle of the load current iL from 0 to p to obtain the average value which is d.c. value of load current. iL = Im sin w t 0 £ wt £ p p p 1 1 · Iav = IDC = i d( wt) = ò I m sin wt dwt pò L p 0
\
I DC =
Load current
o
Imsinwt
p
2p
0
2I m p
for full wave rectifier
TM
Fig. 1.18 Load current waveform
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t
Basic Electronics
1 - 13
Average DC Load Voltage (EDC) :
· The d.c. load voltage is,
E DC = I DC R L =
2I m R L = p
2E sm R + Rs ö æ pç 1 + f ÷ RL ø è
Rf + Rs E sm << 1 and I m = RL Rs + Rt RL
· But as Rf and Rs << RL hence \
Semiconductor Diodes and Applications
2E sm p
E DC =
Rectifier Efficiency (h) : 4 2 Im R L PDC output 8 RL p2 = = \ h = PAC input p 2 (R f + R s + R L ) I 2m (R f + R s + R L ) 2 · But if Rf + Rs << R L , neglecting it from denominator % h max =
\
8 RL p
2
(R L )
=
8 p2
´ 100 = 81.2 %
Ripple Factor (g) : 2
é I RMS ù êI ú -1 ë DC û
Ripple factor =
· For full wave
I RMS = I m
2
and
IDC = 2I m p
2
\
é Im / 2 ù ê 2I / p ú - 1 = ë m û
Ripple factor = g =
so substituting above,
p2 - 1 = 0.48 8
Peak Inverse Voltage (PIV) : + + Esm – + Esm – –
Forward biased
D1
+ RL A
Vo –
B D2 Reverse biased
Voltage across D1 0 –2Esm Voltage across D2 0 –2Esm
Fig. 1.19 PIV Rating of Diodes
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p
2p
3p
4p
p
2p
3p
4p
wt
wt
Basic Electronics
1 - 14
Semiconductor Diodes and Applications
· From Fig. 1.19, when D2 is reverse biased, point A is at – Esm with respect to ground while point B is at + Esm with respect to ground, neglecting diode drop. Thus total peak voltage across D2 is 2Esm. \
PIV of diode = 2 E sm
Ripple Frequency · The Fourier series for the load current is, 2 4 4 iL = i d + i d = I m é cos 2wt cos 4wt Lù úû êë p 3p 1 2 15p
· The lowest frequency of the ripple is 2f. · Thus the ripple frequency in full wave rectifier is '2f" Hz.
Ø
Draw the circuit of bridge rectifier and explain its operation. Give the input and output waveforms. + VTU : Feb.-2000,04, Aug.-01, 06, July-08, Jan.-14, June-13, Marks 5
· The basic bridge rectifier circuit is shown in Fig. 1.20. A D4 Single phase 50 Hz, A.C.Supply
D1
es = Esm sin wt
+ D2
D3
EDC
RL
–
B
Fig. 1.20 Bridge rectifier circuit
Operation of the Circuit : Consider the positive half of ac input voltage. The point A of secondary becomes positive. The diodes D1 and D2 will be forward biased, while D3 and D4 reverse biased. The two diodes D1 and D2 conduct in series with the load and the current flows as shown in Fig. 1.21. A +
D1
A.C. supply
+ –
RL
D2
B
–
Fig. 1.21 Current flow during positive half cycle TM
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Semiconductor Diodes and Applications
· In the next half cycle, when the polarity of ac voltage reverses hence point B becomes positive diodes D3 and D4 are forward biased, while D1 and D2 reverse biased. Now the diodes D3 and D4 conduct is series with the load and the current flows as shown in Fig. 1.22. A –
Direction of load current remains same
D4
A.C. supply
+ RL
D3
+ B
–
Fig. 1.22 Current flow during negative half cycle
· The waveforms of load current and voltage are shown in the Fig. 1.23. (See Fig. 1.23 on next page)
Ø
For a bridge rectifier, derive the expressions for the average d.c. load current, rectifier efficiency, ripple factor and voltage regulation. + VTU : Feb.-03, Marks, 8, Aug.-04, Marks 10, Jan.-08, Marks 6, July-08, Marks 5
· From the equivalent circuit shown in the Fig. 1.24. In each half cycle two diodes conduct simultaneously. Hence maximum value of load current is, Im =
Rf D1
es = Esm sin wt Rs Rf
E sm R s + 2R f + R L
D2
· The PIV rating of the diodes is E sm .
Fig. 1.24
· The remaining expressions are identical to those derived for two diode full wave rectifier. EDC = IDC RL =
2E sm , p
PDC = I 2DC R L =
PAC = I 2RMS (R s + 2R f + R L ) = h =
8R L
p2
(R s + 2R f
g = 0.48 ,
4 p2
I 2m R L
I 2m (2R f + R s + R L ) 2
, % h max = 81.2 % + RL )
T.U.F. = 0.812 TM
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iL
RL
Basic Electronics
1 - 16
Semiconductor Diodes and Applications
es Transformer secondary voltage
Esm 0
p
D1,D2 ON
Current through D1,D2
3p
2p
wt
D3,D4 ON
Im wt Current through D3,D4 Im
wt
Load i current L
Im=
Esm Rs+ 2Rf + RL
Im
Iav = IDC wt
Load voltage
eL wt Voltage across diode
D1
Eav = EDC
Decides PIV rating of diode wt
0 PIV =Esm
–Esm
Fig. 1.23 Waveforms of bridge rectifier
Important Solved Examples Example 1.1
A germanium diode is used in a rectifier circuit and is operating at a temperature
of 25 ºC with a reverse saturation current of 1000 mA. Calculate the value of forward current if it is forward biased by 0.22 V. Assume the value of h = 1 for Ge.
+
Solution :
I0 = 1000 mA = 1000 ´ 10
–6
VTU : Feb.-05, Marks 8
A, h = 1, V = 0.22 V
T = 25 ºC + 273 = 298 ºC VT = kT = 8.62 ´ 10–5 ´ 298 = 0.025 V
TM
... k = Boltzman's constant
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1 - 17
Semiconductor Diodes and Applications
Diode current equation, h VT
I = I0 [e V
-1] = 1000 ´ 10 -6 [e 0.22 / 1 ´ 0.025 - 1] = 6.6332 A
Calculate the reverse saturation current for silicon diode which passes a current of
Example 1.2
10 mA at 27 ºC, for a forward bias of 700 mV. I = 10 mA, V = 700 mV, 'Si' hence h = 2,
Solution :
I = I 0 [e V / hVT – 1] \
i.e.
+
VT = 26 mV for 27 ºC
10 ´ 10 –3 = I 0 [e700 ´ 10
I 0 = 14.2471 nA
Example 1.3
VTU : June-12, Marks 4
–3 /2 ´ 26 ´ 10 –3
- 1]
… Reverse saturation current
A half wave rectifier circuit is supplied from a 230 V, 50 Hz supply with a step
down ratio of 3:1 to a resistive load of 10 kW. The diode forward resistance is 75 W while transformer secondary resistance is 10 W. Calculate maximum, average, RMS values of current, D.C. output voltage, efficiency of rectification and ripple factor. Solution : The circuit is shown in the Fig. 1.25.
Rf = 75 W 230 V, 50 Hz supply
The given values are,
es iL
Rf = 75 W, RL = 10 kW, Rs = 10 W N1: N2 is 3:1
The given supply voltages are always r.m.s. values.
Fig. 1.25
E p ( RMS) = 230 V, N1 3 = N2 1
i.e.
N2 1 = N1 3
N2 E s ( RMS) = N1 E p ( RMS) \
E s ( RMS) 1 = 230 3
\
E s ( RMS) = 76.667 V
This is r.m.s. value of the transformer secondary voltage. 2 E s ( RMS) =
\
Esm =
\
Im =
\
Iav = IDC =
Output
2 ´ 76.667 = 108.423 V
108 .423 E sm = 10.75 mA = Rs + Rf + RL 10 + 75 + 10 ´ 10 3 10 . 75 Im = 3.422 mA = p p TM
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10k W
Basic Electronics
1 - 18
I RMS =
Im 2
for half wave =
Semiconductor Diodes and Applications
10 . 75 = 5.375 mA 2
EDC = D.C. output voltage = IDC RL = 3 . 422 ´ 10 -3 ´ 10 ´ 10 3 = 34.22 V PDC = D.C. output power = EDC IDC = 34.22 ´ 3.422 ´ 10 -3 = 0.1171 W This also can be obtained as, PDC =
I 2m
p2
RL =
(10 . 75 ´ 10 -3 ) 2 p2
´ 10 ´ 10 3 = 0.1171 W
PAC = A.C. input power = I 2RMS[R s + R f + R L ] = (5.375 ´ 10 -3 ) 2 [10 + 75 + 10 ´ 10 3 ] = 0.2913 W \
%h =
PDC 0.1171 ´ 100 = 40.19 % ´ 100 = PAC 0.2913
The ripple factor is constant for half wave rectifier and is 1.21. \ g = 1.21 In a full wave rectifier, the input is from a 30 - 0 - 30 V transformer. The load and diode forward resistance are 100 W and 10 W respectively. Calculate the average voltage, rectification efficiency and percentage regulation.
Example 1.4
+
VTU : Aug.-07, March-01, Marks 7
Solution : Transformer is 30 - 0 - 30 V. It is full wave rectifier with input from center tap transformer. So r.m.s. value of secondary across each half of secondary is 30 V and \ E sm = 2 ´ 30 = 42.4264 V R f = 10 W, RL = 100 W E sm 42.4264 = 0.3856 A = Im = Rf + RL (100 + 10) 2 I m 2 ´ 0.3856 = 0.2455 A = p p
\
I DC =
\
E DC = I DC R L = 0.2455 × 100 = 24.55 V PDC = I 2DC R L = 6.027 W 2
\
æI ö PAC = I 2RMS (R f + R L ) = ç m ÷ (R f + R L ) = 8.1778 W è 2ø P 6.027 % h = D.C. × 100 = ´ 100 = 73.69 % PA.C. 8.1778 % Regulation =
VNL - VFL × 100 VFL
2 VDC no load = VNL = ´ E sm = p
2 ´ 42.4264 = 27.0094 V p TM
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Basic Electronics
1 - 19
VDC full load = VFL = I DC ´ R L = % Regulation = Example 1.5
Semiconductor Diodes and Applications
0.2455 ´ 100 = 24.55 V
27.0094 - 24.55 × 100 = 10.016 % 24.55
A 5 kW load is fed from a bridge rectifier connected across a tranformer secondary
whose primary is connected to 460 V, 50 Hz supply. The ratio of number of primary turns to secondary turns is 2:1. Calculate d.c. load current, d.c. load voltage, ripple voltage and P.I.V. rating of diode. Solution :
R L = 5 kW = 5 ´ 10 3 W, N1 : N2 is 2:1, E p = 460 V
\
N2 Es 1 = = N1 Ep 2
i.e. E s =
RMS value
1 ´ E p = 230 V 2
\
E sm =
now
I DC =
2 Im p
\
I DC =
2 ´ 325.269 2 E sm = 41.41 mA = p RL p ´ 5 ´ 103
2 ´ E s = 230 ´ 2 = 325.269 V. where I m =
E sm neglecting R f . RL
D.C. load voltage E DC = I DC ´ R L = 41.41 ´ 10 –3 ´ 5 ´ 10 3 = 207.072 V Ripple voltage = Ripple factor ´ VDC Ripple factor for bridge rectifier is 0.482. Ripple voltage = 0.482 ´ 207.072 = 99.8 V \ P.I.V. rating of each diode = E sm for bridge rectifier = 325.27 V Example 1.6 In a full wave bridge rectifier, the transformer secondary voltage is 100 sin wt. The
forward resistance of each diode is 25 W and the load resistance is 950 W. Calculate i) D.C. output voltage
ii) Ripple factor
iii) Efficiency of rectification and iv) P.I.V. across non-conducting diode
+
Solution :
VTU : Aug.-2000, Feb.-03, Marks 6
E s = 100 sin wt V, R f = 25 W, R L = 950 W
Comparing E s with E s = E m sin w t, Esm
i)
= 100 V
Im = =
\
I DC =
E sm 2R f + R L
... R s = 0 W
100 = 0.09523 A = 95.238 mA 2 ´ 50 + 950 2 Im 2 ´ 0.09523 = = 0.0606 A = 60.63 mA p p TM
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Basic Electronics
\
1 - 20
Semiconductor Diodes and Applications
E DC = I DC R L = 0.0606 ´ 950 = 57.5985 V 2 éI RMS ù êI ú -1 ë DC û
ii) Ripple factor = I RMS =
Im 2
=
0.09523 = 0.06734 A 2 2
é 0.06734 ù - 1 = 0.4834 ëê 0.06063 ûú
Ripple factor = iii)
P P
\
2
DC
= I DC R L = ( 0.0606) 2 ´ 950 = 3.4921 W
DC
= I 2RMS (2 R f + R L ) = ( 0.06734) 2 ´ ( 2 ´ 50 + 950 ) = 4.7614 W
%h =
PDC 3.4921 ´ 100 = 73.3417 % ´ 100 = PAC 4.7614
iv) P.I.V. rating = E sm for bridge rectifier = 100 V Example 1.7 In a F.W.R. with a capacitor filter, the load current from the circuit operating from
230 V, 50 Hz supply is 10 mA. Estimate the value of capacitor required to keep the ripple
+
factor less than 1 %.
VTU : July-04, Marks 8
Solution : Given, Es(rms) = 230 V, f = 50 Hz, IL = 10 mA, g = 1 % = 0.1. Esm = 2 E s (rms) = 2 ´ 230 = 325.269 V RL =
E DC IL
and EDC =
2E sm p
for full wave
2E sm 2 ´ 325.269 i.e. RL = = 20.7 k W pI L p ´ 10 ´ 10 -3 1 1 To find capacitor value, i.e. 0.01 = g= 4 3f C R L 4 3 ´ 50 ´ C ´ 20.7 ´ 10 +3 C = 13.94 mF
\
RL =
Example 1.8 A full-wave bridge rectifier supplies a load of 400 W in parallel with a capacitor of
500 mF. If the a.c. supply voltage is 230 sin 314t V, find the i) Ripple factor and ii) D. C. load current.
+
VTU : Feb.-07, Marks 6
Solution : Comparing given voltage with v = Vm sin wt, Vm = 230 V, \
w = 314 rad/sec
E sm = Vm = 230 V R L = 400 W, w = 2pf
... As directly applied to rectifier
C = 500 mF w 314 i.e. f = = » 50 Hz 2p 2p TM
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Basic Electronics
1 - 21
g =
i)
Semiconductor Diodes and Applications
1 1 = 0.01443 = 4 3 f CR L 4 3 ´ 50 ´ 500 ´ 10 - 6 ´ 400
ii) Output voltage with filter is, E 1 ù and I DC = DC E DC = E s m - I DC é êë 4 fC úû RL \ \
1 ù I DC R L = E s m - I DC é êë 4fC úû é ù 1 I DC ´ 400 = 230 - I DC ê -6ú ë 4 ´ 50 ´ 500 ´ 10 û
\
I DC = 0.5609 A
Example 1.9 For a zener regulator shown in
R
the Fig. 1.26, calculate the range of input voltage
for
which
output
will
I
remain
IZ
2.2 k W
Vin
constant.
IL Constant 1 kW
VZ = 6.1 V, IZmin = 2.5 mA, IZmax = 25
+ R L Vo = V z –
mA, rZ = 0 W Fig. 1.26
Solution : RL = 1 kW, VZ = 6.1 V \
IL =
VZ 6 .1 = 6.1 mA constant = RL 1 ´ 10 3
For Vin(min), IZ = IZmin = 2.5 mA \ \
I = IZmin + IL = 2.5 +6.1 = 8.6 mA Vin(min) = VZ + IR = 6.1 + 8 . 6 ´ 10 -3 ´ 2 . 2 ´ 10 3 = 25.02 V
For Vin(max), IZ = IZmax = 25 mA \ \
I = IZmax + IL = 25 + 6.1 = 31.1 mA Vin(max) = VZ + IR = 6.1 + 31 . 1 ´ 10 -3 ´ 2 . 2 ´ 10 3 = 74.52 V
Thus the range of input voltage is 25.02 V to 74.52 V, for which output will be constant. Example 1.10 A zener diode has a breakdown voltage of 10 V. It is supplied from a voltage
source varying between 20 - 40 V in series with a resistance of 820 W. Using an ideal zener model obtain the minimum and maximum Zener currents.
+
TM
VTU : Aug.-09, Jan.-14 Marks 8
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Basic Electronics
1 - 22
Semiconductor Diodes and Applications
Solution : The circuit is shown in the Fig. 1.27. R = 820 W
Vo IL
I
Vin 20 - 40 V
RL
Vo = Vz = 10 V
IZ
Fig. 1.27
Vin - Vo I = R \
I = I max
=
Vin -10 820 Vin (max) - 10 820
=
40 - 10 820
=
36.585 mA
I Z min = 0 A Now \ \
...For ideal Zener diode
I = IZ +IL I max
= I Zmin + I L (max )
I L (max) = I max = 36.585 mA
when
IL = IL (min) = 0 A
... Open load terminals
under this condition if Vin = Vin (max) then, I = 36.585 mA and IZ = IZmax = 36.585 mA
Multiple Choice Questions with Answers Introduction to P-N Junction Q.1
A p-n junction forms a popular semiconductor device called _____. (a) rectifier
(b) regulator
(c) diode
(d) triode
(Ans. : c)
Theory of P-N Junction Q.1
The charge movement due to nonuniform doping is called ____. (a) convection
Q.2
(b) diffusion
(c) radiation
(d) displacement (Ans. : b)
In a step graded junction, there is __________ change in the concentrations of charge carriers. (a) abrupt
(b) gradual
(c) zero TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
(d) none of these (Ans. : a)
Basic Electronics
Q.3
(b) charge carriers
(c) magnetic charge
(d) electronic charge (Ans. : b)
The depletion region penetrates more on the ______ doped region. (a) lightly
Q.5
Semiconductor Diodes and Applications
There are no _________ in the space charge region. (a) atoms
Q.4
1 - 23
(b) heavily
(c) equally
(d) none of these (Ans. : a)
Due to diffusion large number of _____ are formed near the junction on p-side. (a) negatively charged immobile ions. (b) positively charged immobile ions. (c) negatively charged charge carriers. (d) positively charged charge carriers. (Ans. : a)
Q.6
Due to diffusion, large number of _____ are formed near the junction on n-side. (a) negatively charged immobile ions. (b) positively charged immobile ions. (c) negatively charged charge carriers. (d) positively charged charge carriers. (Ans. : b)
Q.7
The physical distance from one side to other side of the depletion region is called _____ of depletion region. (a) height
Q.8
(b) width
(c) depth
(d) none of these (Ans. : b)
Practically width of the depletion region is of the order of _____. (a) few nm
(b) few mm
(c) few cm
(d) few mm (Ans. : d)
Q.9
The potential difference across the p-n junction is called _____. (a) barrier potential
(b) photovoltaic potential
(c) cut-out voltage
(d) none of these (Ans. : a)
Q.10
The barrier potential of silicon diode is about _____ volts. (a) 0.8
(b) 0.7
(c) 0.6
(d) 0.2 (Ans. : c)
Q.11
The barrier potential of germanium diode is about _____ volts. (a) 0.8
(b) 0.7
(c) 0.6
(d) 0.2 (Ans. : d)
Q.12
The junction voltage decreases at a rate of ___________ for Si and Ge diodes. (a) 0.7 V/ ºC
Q.13
(b) 2.5 mV/ ºC
(c) 0.2 V/ ºC
(d) none of these (Ans. : b)
_________ does not affect the barrier potential of a diode. (a) Type of semiconductor material
(b) Forward voltage
(c) Temperature
(d) Level of doping (Ans. : b) TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
1 - 24
Semiconductor Diodes and Applications
The P-N Junction Diode Q.1
The contact between metal and heavily doped semiconductor is called _____. (a) resistive contact
(b) permanent contact
(c) ohmic contact
(d) diffused contact (Ans. : c)
Q.2
The device having two electrodes is called ________. (a) transistor
Q.3
(b) diode
(c) rectifier
(d) none of these (Ans. : b)
A device which allows the current flow in one direction but does not allow it in the opposite direction is called ________. (a) transistor
(b) filter
(c) regulator
(d) rectifier (Ans. : d)
Q.4
The p-region in a diode acts as ______. (a) cathode
Q.5
(d) none of these (Ans. : a)
(b) biasing
(c) adjusting
(d) none of these (Ans. : b)
(b) upto 500 mA
(c) upto 1 A
(d) upto 100 mA (Ans. : d)
(b) reverse
(c) electron
(d) none of these (Ans. : a)
The ________current flows from cathode to anode in a diode. (a) forward
Q.10
(c) anode
The arrowhead in the diode symbol points the direction of ________ current . (a) forward
Q.9
(b) electrode
The forward current capacity of a low current diode is _____. (a) upto 200 mA
Q.8
(d) none of these (Ans. : c)
Applying external voltage to any electronic device is called ______. (a) powering
Q.7
(c) anode
The n-region in a diode acts as _____. (a) cathode
Q.6
(b) electrode
(b) reverse
(c) conventional
(d) none of these (Ans. : b)
The barrier potential of a silicon p-n junction is approximately. a) 0.3 V
b) 0.1 V
c) 0.7 V
d) 1.2 V.
+
VTU : Aug.-09 (Ans. : c)
Forward Biasing of Diode Q.1
Which of the following is a forward biased diode ? (a)
R
(b) – + V
(c)
– + V
+ – V
TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
(d) none of these (Ans. : c)
Basic Electronics
Q.2
1 - 25
Due to forward biasing, the depletion region ______. (a) widens
Q.3
(b) narrows
Q.5
(b) –ve of battery
(c) ground
(d) none of these (Ans. : b)
The reciprocal of the slope of the forward characteristics is called ______. (a) reverse resistance
(b) static resistance
(c) saturation resistance
(d) dynamic resistance
_________ represents an ideal diode in the conducting state. (a) A closed switch
Q.6
(c) completely vanishes (d) none of these (Ans. : b)
Forward biasing means connecting n terminal of diode to ______. (a) +ve of battery
Q.4
Semiconductor Diodes and Applications
(b) A resistor
(c) A capacitance
+
(Ans. : d)
VTU : June-13
(d) An open switch (Ans. : c)
When forward-biased, a diode _______. (a) blocks current
(b) conducts current
(c) has a high resistance
(d) drops a large voltage (Ans. : b)
Reverse Biasing of Diode Q.1
Reverse biasing means connecting n terminal of diode to ______. (a) +ve of battery
Q.2
(b) –ve of battery
(c) ground
(d) none of these (Ans. : a)
The voltage at which breakdown of diode occurs is called ______. (a) peak inverse voltage
(b) average voltage
(c) reverse breakdown voltage
(d) valley voltage (Ans. : c)
Q.3
In the reverse breakdown region, the power dissipation is _____________. (a) very high
Q.4
(b) very low
(d) none of these (Ans. : a)
Pulling of electrons from bonds due to intense electric field is called ______. (a) zener effect
Q.5
(c) zero
(b) hall effect
(c) avalanche effect
(d) early effect (Ans. : a)
The diode gets damaged when operated in reverse breakdown region due to excessive _________. (a) voltage
(b) current
(c) power dissipation
(d) none of these (Ans. : c)
Q.6
In p-n diode, as reverse bias voltage increases, the reverse saturation current _____. (a) decreases (c) increases
(b) remains constant (d) none of these (Ans. : b)
TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
Q.7
1 - 26
With increase in the reverse bias, the width of the depletion region _________. (a) decreases
Q.8
(b) remains constant
(c) increases
(d) none of these (Ans. : c)
The reverse current flows due to _____ charge carriers. (a) majority
Q.9
Semiconductor Diodes and Applications
(b) minority
(c) mobile
(d) none of these (Ans. : b)
The reverse current does not depend upon _____. (a) reverse voltage
(b) reverse resistance
(c) temperature
(d) none of these (Ans. : a)
Q.10
For the normal p-n junction, reverse breakdown voltage is greater than ______. (a) 25 V
(b) 30 V
(c) 50 V
(d) 100 V (Ans. : c)
Q.11
Reverse breakdown voltage for silicon diode is ______ that of the germanium diode of comparable rating. (a) less than
Q.12
(b) higher than
(d) none of these (Ans. : b)
_________ represents an ideal diode in the off state. (a) A closed switch
Q.13
(c) equal to
(b) A resistor
(c) A capacitance
In reverse bias the diode can be represented as ________.
(d) An open switch (Ans. : d)
+
VTU : Aug.-09
(a) open circuit
(b) short circuit
(c) a battery of 0.7 V
(d) a current source with constant current. (Ans. : a)
V-I Characteristics of Diode Q.1
The normal forward biased operation of the diode is above the ______ of the characteristics. (a) cut-in point
Q.2
(b) Q point
(c) breakdown point
(d) knee point (Ans. : d)
The forward characteristics are plotted in ______ quadrant. (a) first
(b) second
(c) third
(d) fourth (Ans. : a)
Q.3
The reverse characteristics are plotted in ______ quadrant. (a) first
(b) second
(c) third
(d) fourth (Ans. : c)
Q.4
The forward resistance of the diode is ______. (a) high
(b) infinite
(c) zero
(d) very low (Ans. : d)
Q.5
The ideal value of reverse resistance of the diode is ______. (a) high
(b) infinite
(c) zero
(d) very low (Ans. : b)
TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
Q.6
1 - 27
The breakdown voltage of Si diode is _________ than that of the Ge diode. (a) less
Q.7
Semiconductor Diodes and Applications
(b) greater
(c) same as
(d) none of these (Ans. : b)
The reverse saturation current in silicon diode is of the order of _______. (a) few microamperes
(b) few nA
(c) few mA
(d) none of these (Ans. : c)
Q.8
The reverse saturation current in germanium diode is of the order of _________. (a) few mA
Q.9
(b) few mA
(b) ammeter
(c) oscilloscope
(d) none of these (Ans. : c)
The resistance of a diode under d.c. conditions is called _______ resistance. (a) constant
Q.11
(d) none of these (Ans. : b)
A __________ is used to check the faulty diode. (a) voltmeter
Q.10
(c) few nA
(b) dynamic
(c) static
The Knee voltage of a silicon diode is __________ volts. (a) 0.3 V
(b) 0.5 V
(c) 0.7 V
+
(d) none of these (Ans. : c)
VTU : June-13, Jan.-14
(d) none of these (Ans. : c)
Q.12
The voltage at which forward current through the diode starts increasing rapidly is called VTU : Dec.-11 as _________ .
+
(a) saturation voltage
(b) breakover voltage
(c) cut in voltage
(d) cut off voltage. (Ans. : c)
Diode Current Equation and Nature of Characteristics Q.1
The missing term in the forward diode current equation is ________.
[
]
I F = I 0 eV / VT - 1 (a) VR
Q.2
(b) h
(c) VS
(d) e
(c) 1
(d) 0
(Ans. : b)
The value of h = ______ for germanium. (a) 2
(b) 4
(Ans. : c)
Q.3
The total forward voltage drop across a silicon diode is _____. (a) 0.8 V
(b) 0.5 V
(c) 0.7 V
(d) 0.3 V (Ans. : c)
Q.4
The total forward voltage drop across germanium diode is _____. (a) 0.8 V
(b) 0.5 V
(c) 0.7 V
(d) 0.3 V (Ans. : d)
TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
Q.5
1 - 28
Semiconductor Diodes and Applications
The value of h = _________ for silicon. (a) 2
(b) 4
(c) 1
(d) 0 (Ans. : a)
Q.6
The factor h is called ______. (a) reflection coefficient (c) recombination index
(b) refraction coefficient (d) emission coefficient (Ans. : d)
Q.7
The value of VT = _____ at 300 ºK. (a) 26 mV (b) 30 mV
(c) 15 mV
(d) 5 mV (Ans. : a)
Q.8
The VT is expressed as ______. k (a) kT (b) T
(c)
qk T
(d)
T qk (Ans. : a)
Q.9
In VT = kT, the k is _____. (a) Hall coefficient (c) Maxwell's constant
(b) Planck's constant (d) Boltzmann's constant (Ans. : d)
Q.10
The unit of Boltzmann's constant is ______. (a) eV / º C
(b) º C kg eV
(c) eV / º K
(d) eV (Ans. : c)
Q.11
The value of VT at 40 º C is ______. (a) 26 mV
(b) 26.98 mV
(c) 29.1 mV
(d) 25.9 mV (Ans. : b)
Q.12
The forward current for Ge diode at room temperature for a forward voltage of 0.3 V is ______. (a) 1 mA
Q.13
(b) 1.098 mA
(c) 2.188 mA
The missing terms in the forward diode current is I F = Io [eV (a) VR
(b) h
(d) 0.1091 mA (Ans. : d) VT
(c) VS
– 1] _________ .
+
VTU : Jan.-14
(d) e (Ans. : b)
D.C. Load Line of Diode Q.1
The slope of the d.c. load line is _______ the load resistance. (a) equal to
Q.2
(b) twice
(c) reciprocal
(d) none of these (Ans. : c)
The intersection of the d.c. load line with x-axis is ________. (a) output voltage
(b) supply voltage
TM
(c) diode drop
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(d) none of these (Ans. : b)
Basic Electronics
1 - 29
Semiconductor Diodes and Applications
Rectifiers Q.1
A device converting a.c. to d.c. is called _____. (a) inverter
(b) comparator
(c) rectifier
(d) regulator (Ans. : c)
Q.2
A device which allows the current flow in one direction but does not allow it in the VTU : Jan.-13 opposite direction is called _______.
+
(a) transistor
(b) filter
(c) regulator
(d) rectifier (Ans. : d)
Half Wave Rectifier Q.1
The output voltage waveform of Fig. 1.28 corresponds to a ___ rectifier. (a) negative FWR
(b) positive FWR
(c) negative HWR
(d) positive HWR
Vo p
0
t
Fig. 1.28
(Ans. : d)
Q.2
2p
In half wave rectifier, the diode conducts for ______ of the input a.c. voltage cycle. (a) 180º
(b) 0º
(c) 360º
(d) 270º (Ans. : a)
Q.3
For a half wave rectifier IDC = _________. I 2I (b) m (a) m 2p p
(c) p Im
Im p
(d)
(Ans. : d)
Q.4
For a half wave rectifier I RMS = __________. (a) Im
(b)
Im 2
(c)
Im 2
(d)
2 Im (Ans. : b)
Q.5
The maximum efficiency of half wave rectifier is ______. (a) 40.6 %
Q.6
(b) 60.4 %
(c) 78.5 %
The ripple factor of half wave rectifier is ______. (a) 1.4
(b) 0.48
(c) 1.211
(d) 81.2 %
+
(Ans. : a)
VTU : June-13
(d) 1.71 (Ans. : c)
Q.7
PIV rating of diode in half wave rectifier is ______. (a) 2 Esm
(b) Esm
(c)
Esm 2p
(d) none of these. (Ans. : b)
Q.8
The peak current I m in a HWR is ____. (a)
Em Rs + Rf + 2RL
(b)
Em 2 Rs + Rf + RL
TM
(c)
Em RL
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(d)
Em Rs + Rf + RL (Ans. : d)
Basic Electronics
Q.9
1 - 30
Semiconductor Diodes and Applications
The a.c. power input to a HWR is ____. (a)
I 2m ´ (RL + Rf + Rs) 4
(b)
I 2m ´ (2RL + Rf + Rs) 4
(c)
I 2m ´ (RL + 2Rf + Rs) 2
(d)
I 2m ´ (RL + Rf + Rs) 2 (Ans. : a)
Q.10
The r.m.s. current in half wave rectifier is ____. (a)
Im 2p
(b)
2 Im p
(c)
Im 2
(d)
Im 2
+
VTU : Jan.-11, July-11 (Ans. : c)
Q.11
The ripple frequency in a HWR is ____ Hz. (a) 50
(b) 100
(c) 200
(d) 0 (Ans. : a)
Q.12
If the r.m.s. secondary voltage to half wave rectifier is 22.2144 V then its output voltage is ____. 10 (d) (a) 20 V (b) 10 V (c) 10 2 V p (Ans. : b)
Q.13
For having the ideal voltage regulation for a half wave rectifier, ____. (a) RL = 0
Q.14
(b) Rf = 0
(c) (Rs + Rf ) = 0
(d) none of these (Ans. : c)
In a power supply, the ripple factor is defined as ___. (a)
é I 2RMS ù ê 2 ú -1 êë I DC úû
(b)
é I RMS ù -1 ëê I DC ûú
(c)
é I 2RMS ù ê 2 - 1ú êë I DC úû
2
(d) none of these (Ans. : a)
Q.15
A half wave rectifier is fed from secondary of a transformer whose output voltage is 12.6 V. The DC voltage of the rectifier output is ----------. (a) 12.6 V
(b) 5.66 V
(c) 17.8 V
(d) 11.32 V (Ans. : b)
Q.16
The average output voltage of half wave rectifier with an input of 300 sin 314t is ___________ . (a) 100 V
(b) 95.49 V
(c) 90.49 V
(d) 90.0 V (Ans. : b)
Q.17
PIV in case of half wave rectifier for an input signal of Vm sin w t is _______.
+
(a) Vm
V (c) m 2
(b) 2Vm
VTU : June-12
V (d) m 2 (Ans. : a)
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1 - 31
Semiconductor Diodes and Applications
Full Wave Rectifier Q.1
The peak current I m in a FWR is ____. (a)
Q.2
Em Rs + Rf + 2RL
(b)
Em 2 Rs + Rf + RL
(c)
Em RL
(d)
Em Rs + Rf + RL (Ans. : d)
The a.c. power input to a FWR is ____. (a)
I 2m ´ (RL + Rf + Rs) 4
(b)
I 2m ´ (2RL + Rf + Rs) 4
(c)
I 2m ´ (RL + 2Rf + Rs) 2
(d)
I 2m ´ (RL + Rf + Rs) 2 (Ans. : d)
Q.3
The r.m.s. current in full wave rectifier is ____. (a)
Im 2p
(b)
2 Im p
(c)
Im 2
(d)
Im 2 (Ans. : d)
Q.4
The ripple frequency in a FWR is ____ Hz. (a) 50
(b) 100
(c) 200
(d) 0 (Ans. : b)
Q.5
The percentage of a.c. component in the rectifier output is measured by _____. (a) ripple factor
Q.6
(b) regulation
(c) TUF
(d) load resistance (Ans. : a)
In full wave rectifier, the diode conducts for ______of the input a.c. voltage cycle. (a) 180º
(b) 0º
(c) 360º
(d) 270º (Ans. : c)
Q.7
For a full wave rectifier IDC = _________. (a)
Im 2p
(b)
2Im p
(c) p Im
(d)
Im p (Ans. : d)
Q.8
For a full wave rectifier I RMS = _______. (a) Im
Q.9
Im 2
(c)
Im 2
The maximum efficiency of full wave rectifier is ______. (a) 40.6 %
Q.10
(b)
(b) 60.4 %
(c) 78.5 %
(b) 0.48
2 Im
+
(c) 1.211
(Ans. : c)
VTU : Jan.-14
(d) 81.2 %
+
The ripple factor of full wave rectifier is ______. (a) 1.4
(d)
(Ans. : d)
VTU : Jan.-13
(d) 1.71 (Ans. : b)
Q.11
PIV rating of diode in full wave rectifier is ______. (a) 2 Esm
(b) Esm
(c)
Esm 2p
(d) none of these
+
VTU : Jan-11 (Ans. : a)
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Q.12
1 - 32
Semiconductor Diodes and Applications
The ideal value of voltage regulation is _____. (a) 0
(b) ¥
(c) very high
(d) none of these (Ans. : b)
Q.13
Ideally the ripple factor should be _____. (a) ¥
Q.14
(c) 100
(d) none of these (Ans. : b)
The ideal value of the rectifier efficiency is _____. (a) ¥
Q.15
(b) 0
(b) 0
(c) 100
(d) none of these (Ans. : c)
The two secondary voltages of a centre tap transformer are _____. (a) equal magnitude and 180º shifted in phase (b) equal magnitude and 90º phase shifted (c) equal magnitude and 0º phase shifted (d) none of these (Ans. : a)
Q.16
The expression for load regulation of a full wave rectifier is ______. (a)
RL Rs + Rf
(b)
Rs + Rf RL
(c)
Rs RL + Rf
(d) none of these (Ans. : b)
Q.17
The peak current I m of a full wave rectifier is ___ as that of a half wave rectifier if all the parameters of diode, load and transformer are identical. (a) half
(b) twice
(c) four times
(d) same (Ans. : d)
Q.18
The ripple factor of a power supply means a measure of ______. (a) a.c. component of output waveform
(b) amplitude of output waveform
(c) shape of output waveform
(d) frequency of output waveform (Ans. : a)
Q.19
The average load current of a full wave rectifier is ___ as that of half wave rectifier. (a) twice
(b) half
(c) four times
(d) same (Ans. : a)
Q.20
The average output voltage of a full wave rectifier is ____ as that of half wave rectifier. (a) four times
(b) half
(c) twice
(d) same (Ans. : c)
Q.21
The TUF indicates ___. (a) efficiency of transformer. (b) how effectively the transformer is utilized. (c) regulation of transformer. (d) loading of transformer. (Ans. : b)
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Q.22
1 - 33
Semiconductor Diodes and Applications
TUF is defined as the ratio of ___. (a) d.c. output power to a.c. power rating of the transformer. (b) a.c. input power to d.c. output power. (c) d.c. output power and a.c. input power. (d) a.c. power rating of the transformer
to d.c. output power. (Ans. : a)
Q.23
While selecting a diode for a rectifier circuit, the important voltage specification that is considered is ____. (a) junction potential
(b) supply voltage
(c) reverse breakdown voltage
(d) PIV (Ans. : d)
Q.24
The efficiency of full wave rectifier is about __________ %. (a) 40.6
(b) 0.46
(c) 1.21
(d) 81.2 (Ans. : d)
Q.25
If frequency of input is 60 Hz for a fullwave rectifier, the frequency of ripple is ________. (a) 30 Hz
(b) 60 Hz
(c) 120 Hz
(d) 180 Hz (Ans. : c)
Q.26
If peak to peak voltage is 4 V then RMS voltage is _________. (a)
Q.27
2 Volts
(b) 2 Volts
(c) 2.82 Volts
(d) both (A) and (C) (Ans. : a)
The rms value of a load current in case of a full wave rectifier is _______. (a)
p 2
(b)
Im 2
(c)
Im 2
(d)
Im p (Ans. : c)
Bridge Rectifier Q.1
The peak current Im in a bridge rectifier is ____. (a)
Q.2
Em Rs + Rf + 2RL
(b)
Em Rs + 2 Rf + RL
(c)
Em RL
(d)
Em Rs + Rf + RL (Ans. : b)
The a.c. power input to a bridge rectifier is ____. (a)
I 2m ´ (RL + Rf + Rs) 4
(b)
I 2m ´ (2RL + Rf + Rs) 4
(c)
I 2m ´ (RL + 2Rf + Rs) 2
(d)
I 2m ´ (RL + Rf + Rs) 2 (Ans. : c)
Q.3
In a bridge rectifier, ______ diodes conduct in each half cycle. (a) one
(b) three
(c) four
(d) two (Ans. : d)
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Q.4
1 - 34
Semiconductor Diodes and Applications
PIV rating of a diode in a bridge rectifier is ______. (a) Esm
(b) 2Esm
(c)
Esm p
(d) p Esm
+
VTU : July-11 (Ans. : a)
Q.5
The no load condition implies that _____. (a) I L = ¥
Q.6
(b) RL = 0
(c) RL = ¥
(d) none of these (Ans. : c)
In a bridge rectifier, the nput is from 230 V, 50 Hz; the DC output voltage is (a) 200V
(b) 207V
(c) 315V
+
(d) 220V
VTU : Jan.-11 (Ans. : b)
Q.7
The transformer utilization factor of a bridge type full wave rectifier is _______ . (a) 0.287
(b) 0.812
(c) 0.864
(d) 0.48
(Ans. : b)
Capacitor Input Filter (C Filter) Q.1
For a full wave rectifier with capacitor filter diode conducts for ___ half cycle. (a) more than
Q.2
(b) less than
(c) equal to
(d) none of these (Ans. : b)
If looking from rectifier side, the first element in the filter is a capacitor then it is called ______ filter. (a) choke input
(b) capacitor
(c) p
(d) RC (Ans. : b)
Q.3
If capacitor value increases in a capacitor filter then the ripple factor ______. (a) increases
Q.4
(b) becomes zero
(c) decreases
(d) none of these (Ans. : c)
The ripple factor for the capacitor filter is _____ for full wave rectifier. (a)
1 4 3 f C RL
(b)
1 2fCRL
(c)
1 2pfCRL
(d)
1 pfCRL (Ans. : a)
Q.5
The filter removes _____ to obtain pure d.c. (a) ripples
(b) interference
(c) noise
(d) hum (Ans. : a)
Q.6
In a filter circuit _____ is always connected in series with the load. (a) capacitor
Q.7
(c) inductor
(d) none of these (Ans. : c)
In a filter circuit _____ is always connected in parallel with the load. (a) capacitor
Q.8
(b) resistor
(b) resistor
(c) inductor
(d) none of these (Ans. : a)
The ripple factor _____ as the value of filter capacitor increases. (a) remains same
(b) decreases
(c) increases TM
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(d) none of these (Ans. : b)
Basic Electronics
Q.9
1 - 35
The capacitor filter is suitable for ____. (a) heavier loads
Q.10
Semiconductor Diodes and Applications
(b) constant loads
(c) lighter loads
(d) none of these (Ans. : b)
In Fig. 1.29 a diode in full wave rectifier with capacitor filter turns on at a point ___. (a) A
(b) O
(c) B
(d) C
A
t
Fig. 1.29
A ____ type of capacitor is generally used as a filter. (a) electrolytic
Q.12
C
0
(Ans. : c)
Q.11
B
(b) mica
(c) polysterene
(d) none of these (Ans. : a)
In the capacitor filter a resistance is used in series with C for : (a) increasing efficiency
(b) reducing surge current
(c) reducing the oscillations (Ans. : b)
Q.13
The output voltage of a rectifier with filter at no load is : (b) Vm 2
(a) 2Vm
(c) Vm
(d) none of these (Ans. : c)
Q.14
The average output voltage of a capacitor filter with a full wave or bridge rectifier is _______. V I 4 f I DC I (b) Esm - DC (c) Esm (d) Esm - DC (a) Esm - DC 4fC 4fC C 2fC (Ans. : b)
Q.15
The average output voltage of a capacitor filter with a half wave is _______. (a) Esm -
Q.16
VDC 4fC
(b) Esm -
I DC 4fC
(c) Esm -
4 f I DC C
(d) Esm -
I DC 2fC (Ans. : d)
A bridge rectifier uses a capacitor of 100 mF as a filter with a load resistance of 1 kW . Its ripple factor for frequency of 50 Hz is _____. (a) 0.0288
(b) 0.288
(c) 0.144
(d) 0.0144 (Ans. : a)
Q.17
Smaller the ripple factor, the output will have higher _____components.
+
(a) a.c.
(b) d.c.
(c) both a.c. and d.c.
VTU : Dec.-11
(d) pulse (Ans. : b)
Power Supply Performance Q.1
The output voltage of a zener regulator is equal to ____. (a) VZ - I R
(b) I Z max ´ rZ
(c) VZ
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(d) none of these (Ans. : c)
Basic Electronics
Q.2
1 - 36
Semiconductor Diodes and Applications
The output voltage of zener regulator shown is _____. 10 kW
20 V
(a) 20 V
2 kW
6V
(b) 12 V
(c) 6 V
(d) 15 V (Ans. : c)
Q.3
The maximum value of zener current in the circuit shown is ______. 2 kW
+ 30-80 V
(a) 1.2 mA
Q.4
(b) 32.8 mA
10 kW
(c) 35.2 mA
(d) None of these (Ans. : b)
(b) 9 mA
(c) 10.2 mA
(d) none of these (Ans. : a)
Zener diode used as a voltage regulator when it is __________ biased. (a) Forward
Q.6
–
The minimum value of zener current in the above circuit is ____. (a) 7.8 mA
Q.5
12 V
(b) Reverse
(c) Unbiased
(d) None of these. (Ans. : b)
Zener diode regulates only when it is connected in ______ mode. (a) Forward bias
(b) Reverse bias
(c) short
(d) Open.
+
VTU : July-11 (Ans. : b)
Zener Diode as a Shunt Regulator Q.1
Dynamic zener resistance is _________ in reverse breakdown condition.
+
(a) very high
Q.2
(b) high
(c) zero
The zener power dissipation is given by the product of _______. (a) VR , IZ
(b) VF , IZ
(c) VZ IZ
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VTU : Dec.-11
(d) very small (Ans. : d)
+
VTU : Jan.-13
(d) none of these (Ans. : c)
Basic Electronics
Q.3
1 - 37
Semiconductor Diodes and Applications
The zener diode is mainly used in _________ . (a) Comparator
(b) Regulator
(c) Multivibrator
+
VTU : Jan.-14
(d) None of these (Ans. : b)
Clipper Circuits or Limiters Q.1
The circuits used to remove unwanted portion of waveform without distorting the remaing part are called _____. (a) clippers
(b) clampers
(c) d.c. restorers
(d) filters (Ans. : a)
Q.2
______ is the simplest type of clipper. (a) Filter
Q.3
(d) Integrator (Ans. : b)
The clipper circuits are also called ______. (a) filters
Q.4
(b) Half wave rectifier (c) Chopper
(b) rectifiers
(c) limiters
(d) integrators (Ans. : c)
(c) Zener
(d) Inductor
______ is main element of a clipper. (a) Diode
(b) Transistor
(Ans. : a)
Series Clippers Q.1
In a series clipper, ________ is connected in series with the load. (a) diode
(b) inductor
(c) transistor
(d) capacitor (Ans. : c)
Q.2
A negative clipper clips off ________ portion of the input waveform. (a) positive
Q.3
(c) peak
(d) none of these (Ans. : a)
A positive clipper clips off ________ portion of the input waveform. (a) positive
Q.4
(b) negative
(b) negative
(c) peak
(d) none of these (Ans. : c)
In a series clipper, for a clipping region, the diode must be in ________ condition. (a) forward biased
(b) reverse biased
(c) none of these (Ans. : b)
Q.5
In a series clipper, for a transmitting region, the diode must be in ________ condition. (a) forward biased
(b) reverse biased
(c) none of these (Ans. : c)
Q.6
In a series clipper, the slope of the transfer characteristics in transmitting region is ______ . (a) zero
(b) unity
(c) infinite
(d) negative (Ans. : a)
Q.7
In a series clipper, the slope of the transfer characteristics in clipping region is ________ . (a) zero
(b) unity
(c) infinite
(d) negative (Ans. : c)
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Q.8
1 - 38
In a series clipper, when diode is OFF, it produces ______ region of the clipper. (a) transmitting
Q.9
(b) clipping
(c) linear
(d) none of these (Ans. : b)
In a series clipper, when diode is ON, it produces ______ region of the clipper. (a) transmitting
Q.10
Semiconductor Diodes and Applications
(b) clipping
(c) linear
(d) none of these (Ans. : a)
The graph of output variable against input variable is called ______ characteristics of the circuit. (a) linear
(b) nonlinear
(c) transfer
(d) V-I (Ans. : c)
Shunt or Parallel Clippers Q.1
In a ________ clipper, a diode is connected in parallel with the load. (a) series
(b) combinational
(c) parallel
(d) two way (Ans. : c)
Q.2
In a parallel clipper, Vo = Vin can be obtained in transmitting region by making ________. (b) R1 = RL (c) R1 << RL (d) None of these (a) R1 >> RL (Ans. : c)
Q.3
In a parallel clipper, the slope of the transfer characteristics in transmitting region is _____. (a) unity
Q.4
(c) depends on RL and R1
(b) zero
(d) infinite (Ans. : c)
In a parallel clipper, the slope of the transfer characteristics in clipping region is ______. (a) unity
(c) depends on RL and R1
(b) zero
(d) infinite (Ans. : b)
Two Way Clippers (Biased Shunt Clippers) Q.1
A circuit producing both positive and negative clipping is called ______ clipper. (a) series
(b) parallel
(c) two way
(d) four way (Ans. : c)
Clamper Circuits Q.1
In a ________ clamper, the capacitor gets charged during first quarter of the positive cycle of the input. (a) negative
(b) positive
(c) combinational
(d) two way (Ans. : a)
Q.2
In a ________ clamper, the capacitor gets charged during first quarter of the negative cycle of the input. (a) negative
(b) positive
(c) combinational
(d) two way (Ans. : b)
Q.3
One charged to peak value, a capacitor acts as ________ in a clamper. (a) filter
(b) multiplier
(c) battery
(d) rectifier (Ans. : c)
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Q.4
Semiconductor Diodes and Applications
Due to large ________, capacitor holds its entire charge. (a) charging current
Q.5
1 - 39
(b) time constant
(c) discharging current
(d) none of these (Ans. : b)
Due to the ________ time constant, the capacitor holds its entire charge. (a) zero
(b) negative
(c) very large
(d) unity (Ans. : c)
Q.6
In a clamper, the analysis must start considering that part of the input which ________. (a) reverse biases the diode
(b) forward biases the diode
(c) discharges the capacitor
(d) none of these (Ans. : b)
Q.7
________ is assumed in the clamper. (a) Capacitor charges exponentially and discharges instantly (b) Capacitor charges instantly and discharges instantly (c) Capacitor charges instantly but does not discharge at all (d) Capacitor charges exponentially and discharges exponentially (Ans. : c)
Q.8
The circuits used to add a d.c. level to the output are called ______. (a) clippers
(b) slicers
(c) limiters
(d) clampers (Ans. : d)
Q.9
The clampers are also called ______ circuits. (a) clipper
(b) d.c. restorer
(c) limiter
(d) slicer (Ans. : b)
Q.10
In a clamper, ______ is necessary in addition to a diode. (a) inductor
Q.11
(c) capacitor
(d) none of these (Ans. : c)
In a clamper, total swing of the output is ______ the total swing of the input. (a) greator than
Q.12
(b) transistor
(b) less than
(c) equal to
(d) none of these (Ans. : c)
In a cameras for the flash circuit ______ is used. (a) clipper
(b) clamper
(c) limiter
(d) rectifier (Ans. : b)
qqq
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Semiconductor Diodes and Applications
Notes
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2
Bipolar Junction Transistor
Chapter at a Glance Important Definitions 1. Transistor is a three terminal device : Base, emitter and collector, can be operated in three configurations common base, common emitter and common collector. 2. Unipolar transistor : The transistor in which current conduction is in only one type of charge carriers, majority carriers. 3. Bipolar transistor : The transistor in which current conduction is due to two types of carriers viz holes and electrons. 4. Doping : The process by which impurities are added to a pure semiconductor is called doping.
+
5. Define a dc and b dc .
VTU : Mar.-2000, 05, Aug.-01, Feb.-10
a dc is the fraction of IE that crosses over from emitter to the collector region. I -I a dc = C CBO IE a dc = a »
IC IE
when ICBO ® 0
bdc : It is defined as the ratio of the collector current to the base current. I \ bdc = b = C IB Typical values : a = 0.9 to 0.99
b = 100 to 300
6. Current amplifier : In a transistor circuit, when output current is greater than input current, the circuit is known as current amplifier. 7. Voltage amplifier : In a transistor circuit, when the output voltage is greater than the input voltage, the circuit is known as voltage amplifier. 8. Active region : For the operation in the active region, the emitter-base junction (JE) is forward biased while collector base junction (JC) is reverse biased.
(2 - 1) TM
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2-2
Bipolar Junction Transistor
9. Saturation region : In this region, the emitter-base junction (JE) and collector base junction (JC) both are forward biased. 10. Cut-off region : The region below the curve I E = 0 is known as cut-off region, where the collector current is nearly zero and the collector-base (JC) and emitter-base (JE) junctions of a transistor are reverse biased. 11. Define current gain of CC configuration : The current gain of CC configuration is given by g =
IE I +I I a 1 = = B C = 1 + C = 1 +b= 1 + IB IB IB 1 -a 1 -a
Important Formulae 1.
IE = IB + IC
2.
a dc = a »
IC IE
3.
b dc = b @
IC IB
4.
b =
a 1 -a
5.
a =
b 1 +b
6.
b ac =
Ic Ib
7.
Av =
Vo Vi
8.
g =
... Voltage gain
I 1 @ E 1 -a IB
Important Questions and Answers
Ø
+
Explain the word transistor.
VTU : Feb.-02, Marks 5
· The amplification in the transistor is achieved by passing input current signal from a region of low resistance to a region of high resistance. This concept of transfer of resistance has given the name TRANSfer-resISTOR (TRANSISTOR).
Ø
Clearly show the biasing arrangement of a NPN transistors for conduction. + VTU : Feb.-02, Marks 3
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2-3
Bipolar Junction Transistor
· The base to emitter junction is forward biased by the d.c. source VEE . Thus, the depletion region at this junction is reduced. The collector to base junction is reverse biased, increasing depletion region at collector to base junction as shown in Fig. 2.1.
· The forward biased EB junction causes the electrons in the n-type emitter to flow towards the base. This constitutes the emitter current I E . As these electrons flow through the p-type base, they tend to combine with holes in p-region (base). · Due to light doping, very few of the electrons injected into the base from the emitter recombine with holes to constitute base current, IB and the remaining large number of electrons cross the base region and move through the collector region to the positive terminal of the external d.c. source. · This constitutes collector current I C . Thus the electron flow constitutes the dominant current in an npn transistor.
· Since, the most of the electrons from emitter flow in the collector circuit and very few combine with holes in the base. Thus, the collector current is larger than the base current. The relationship between these current is given by I E = IC + I B Current limiting resistor
BE depletion
RE
– VEE
+
E
+ + + + + + + +
n
– – – – – – – –
Current limiting resistor
BC depletion – – – – – – – –
p
– – – – – – – –
BE Junction forward biased
– – – – – – – –
+ + + + + + + +
+ + + + + + + +
+ + + + + + + +
n
C
RC
BC Junction reverse biased
+ –
VCC
Vb Barrier voltage
Vb
B
Fig. 2.1
Ø
Write equations for collector current (I C ) in terms of emitter current (I E ) and a dc , and in terms + VTU : Feb.-10, July-11, Marks 5 of base current (I B) and a dc .
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Ø
2-4
Bipolar Junction Transistor
Draw a sketch to show the various current components in a NPN transistor and deduce the relation between various current components. + VTU : Feb.-08, July-11, Marks 8
· The directions of conventional currents in an npn transistor are as shown in Fig. 2.2 (a) and Fig. 2.2.5 (c) and those for a pnp are shown in Fig. 2.2 (b) and 2.2 (d). Figures show the conventional currents using the schematic symbols of npn and pnp transistors, respectively. · It can be noticed that the arrow at the emitter of the transistor’s symbol points in the direction of conventional current. · Let us consider pnp transistor. The current flowing into the emitter terminal is referred to as the emitter current and identified as I E . The currents flowing out of the collector and base terminals are referred to as collector current and base current, respectively.
+
VEE
IB
–
+
VCC
p
IE
–
+
IC
–
IB
VEE
(a)
–
p
n
V + CC
(b)
IC
IE VEE
+ –
IB
+
VCC
–
(c)
IC
IE VEE IB
+
+
IE
IC
n
–
–
p
n
VCC
(d) Fig. 2.2 Transistor conventional current directions
The collector current is identified as I C and base current as I B . For both npn and pnp transistors. IE = IB + IC
Ø
Establish the relationship between a and b . + VTU : Mar.-2000 ,01, 05, Aug.-01, Feb.-09, Jan.-11, July-13, Marks 4
We know that, b = We have,
IC IB
IE = IC + IB b =
i.e. I B = I E – I C
IC IE – IC
Q IB = IE – I C
Dividing the numerator and denominator of R.H.S. of above equation by I E , we get, TM
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Basic Electronics
2-5
b =
IE
IC IE IE – IC IE
b=
a 1– a
We know that, a =
IC IE
\
a =
Bipolar Junction Transistor
Q a=
IC IE
and I E = I B + I C
IC IB + IC
Dividing the numerator and denominator of R.H.S. of above equation by I B , we get, a = \
Ø Ø Ø
a=
IB
IC IB IB + IC IB
b 1+ b
Q b=
IC IB
A transistor is capable of providing amplification; Explain the basic transistor amplifier with suitable diagrams. + VTU : Aug.-03, Marks 6 Show that a transistor could be used as an amplifier.
+
VTU : June-06, Aug.-08, Marks 5
Explain how current amplification can be achieved in the transistor circuit.
· We have seen that b dc = I C / I B . It is the current gain from the base to collector. Since I B is small and I C is large and they relate with a factor b dc , a small change in the I B (D I B ) produces a large change in I C (D I C ). This is illustrated in the Fig. 2.3 RC
+DIC
IC + DIC – IB + DIB –
VBB
+
Q1
–
IB
+ –
IE + DIE –
IC
VCC
0
+DIB
–DIC
–DIB 0
Fig. 2.3 Illustration for the current amplification
· The increasing and decreasing levels of base and current currents due to change may be defined as alternating quantities. The alternating current gain therefore, may be stated as TM
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2-6
b ac =
Bipolar Junction Transistor
Ic Ib
where, b ac : Alternating current gain I c : a.c. collector current indicated by lower-case subscript I b : a.c. base current indicated by lower-case subscript The ac current gain is also denoted as h fe .
Ø
With a neat circuit diagram explain the working of transistor used as voltage amplifier. + VTU : Jan.-14, Marks 4
· The Fig. 2.4 shows the transistor circuit with a base bias and signal generator. Let us assume that the transistor, Q 1 in the circuit has b dc = 100. The base bias of 0.7 V forward biases the base-emitter junction of transistor. An ac signal source, v i in series with VBB provides ± 10 mV input voltage.
+ IC RB
Q1
IB
vi
+ – 10 mV
VB
+ VBB (0.7 V) –
· Now let us observe the changes in I B and I C due to changes in v i from the V-I characteristics of transistor given in Fig. 2.5
RC IC RC 10 K – +
–
Fig. 2.4
IB(mA) IB at VB = VBB+ vi
20
IB at VB = VBB
15
IB at VB = VBB – vi
10
VB = VBB – vi VB = VBB VB = VBB + vi
5
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
VBE(V)
Fig. 2.5 VBE versus I B characteristics of transistor TM
–
VCE
IE
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+
VCC
Basic Electronics
2-7
Bipolar Junction Transistor
Condition 1 : When v i = 0, VB = VBB = 0.7 and I B = 15 mA. \ I C = 15 mA ´100 = 1.5 mA Condition 2 : When v i = – 10 mV, VB = VBB - v i = 0.7 – 10 mV = 0.69 V I B = 10 mA \
I C = 10 mA ´ 100 = 1 mA
Condition 3 :
When v i = 10 mV
VB = VBB + v i = 0.7 + 10 mV = 0.71 V I B = 20 mA \
I C = 20 mA ´ 100 = 2 mA
· Therefore, change in I C (D I C ) = 2 mA – 1 mA = 1 mA due to ± 10 mV change in v i . The change in the output voltage VC can be given by D VC = D I C R C = 1 mA ´ 10 kW = 10 V
· Therefore, the ac voltage gain which is the ratio of change in output voltage to change in input voltage is given by D VC D VC 10 V = 500 = = Av = D VB D vi 20 mV · Since the output voltage is greater than the input voltage, the circuit has a voltage gain and it is a voltage amplifier. · The voltage change across R C is an ac output voltage denoted as v o . Therefore, the equation for ac voltage gain is given by vo Av = vi
Ø
Sketch and explain the input characteristics of transistor in CB mode.
+
VTU : Feb.-09, July-13
· It is the curve between and input voltage VEB (emitter-base voltage) and input current I E (emitter current) at constant collector-base voltage VCB . The emitter current is taken along Y-axis and emitter base voltage along X-axis. Fig. 2.6 shows the input characteristics of a typical transistor in common-base configuration.
· From this characteristics we can observe the following important points : 1. The input resistance is a ratio of change in emitter-base voltage (DVEB ) to the resulting change in emitter current (D I E ) at constant collector-base voltage (VCB ). It is given by ri =
D VEB DI E
VCB = constant TM
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2-8
Bipolar Junction Transistor
|IE|(mA)
Emitter-base current
3.5 3.0
|VCB| = 10 V |VCB| = 5 V
2.5
Note : While plotting input characteristics the magnitudes of voltage and current are considered. Practically the voltage and current polarities are opposite for pnp and npn transistors
2.0 1.5
|D IE|
1.0 0.5
|D VEB| 0.5 1.0 1.5 2.0 Emitter-base voltage
|VEB|(V)
Fig. 2.6 Input characteristics of transistor in CB configuration
2. After the cut-in voltage (barrier potential, normally 0.7 V for silicon and 0.3 V for germanium), the emitter current (I E ) increases rapidly with small increase in emitter-base voltage (VEB ). Thus, the input resistance is very small.
3. It can be observed that there is slight increase in emitter current (I E ) with increase in VCB . This is due to change in the width of the depletion region in the base region under the reverse biased condition. 4. VCB is positive for npn transistor and it is negative for pnp transistor. On the other hand VEB is negative for npn transistor and it is positive for pnp transistor.
Ø
With a neat diagram explain the output characteristics of transistor in CB mode. + VTU : Feb.-02, 09, July-13, Marks 8
· It is the curve between collector current I C and collector base voltage VCB at constant emitter current I E . The collector current is taken along Y-axis and collector-base voltage magnitude along X-axis. Fig. 2.7 shows the output characteristics of a typical transistor in common base configuration. From this characteristics we observe following points : 1. The output characteristics has three basic regions : Active, cut-off and saturation. 2. Active Region : n For the operation in the active region, the emitter-base junction (JE) is forward biased while collector base junction (JC) is reverse biased. n
n
In this region, collector current I C is approximately equal to the emitter current ( I E ) and transistor works as an amplifier. In the active region, the collector current is essentially almost constant.
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2-9
Bipolar Junction Transistor
|IC|(mA) DIE
Active region
5
|IE| = 5 mA
DVCB
|IE| = 4 mA
Saturation region
Collector current
4
3
|IE| = 3 mA
2
|IE| = 2 mA
1
|IE| = 1 mA
Note : While plotting output characteristics the magnitudes of voltage and current are considered. Practically the voltage and current polarities are opposite for pnp and npn transistors
|IE| = 0 –1
0
|VCB| (V)
5 10 15 20 Collector-base voltage
Cut-off region
Fig. 2.7 CB output characteristics n
The Dynamic output resistance is the ratio of change in collector base voltage ( DVCB ) to the resulting change in collector current (DI C ) at constant emitter current (I E ). It is given by Ro =
D VCB DI C
I E = Constant
The collector current I C is almost independent on collector-base voltage VCB and the transistor can be said to work as constant-current source. This provides very high dynamic output resistance. 3. Saturation Region : In this region, the emitter-base junction (JE) and collector base junction (JC) both are forward biased. Here, the IC is independent of IE.
n
4. Cut-off Region : The region below the curve I E = 0 is known as cut-off region, where the collector current is nearly zero and the collector-base (JC) and emitter-base (JE) junctions of a transistor are reverse biased.
Ø
Sketch and explain the input characteristics of transistor in CE mode. + VTU : Feb.-04, 08, Aug.-08, 09, Jan.-11
· It is the curve between and input voltage VBE (base-emitter voltage) and input current I B (base current) at constant collector-emitter voltage, VCE . The base current is taken along Y-axis and base emitter voltage VBE is taken along X-axis. Fig. 2.8 shows the input characteristics of a typical transistor in common-emitter configuration.
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Bipolar Junction Transistor
From this characteristics we observe the following important points : |IB|(mA) 80
Base current
70 60 50
|VCE| = 5 V
|VCE| = 20 V
D IB
40 30 20 10
D VBE 0.5 1.0 1.5 Base-emitter voltage
Note : While plotting input characteristics the magnitudes of voltage and current are considered Practically the voltage and current polarities are opposite for pnp and npn transistors
|VBE|(V)
Fig. 2.8 Input characteristics of the transistor in CE configuration
1. The input resistance is the ratio of change in base-emitter voltage (DVBE ) to the resulting change in base current (DI B ) at constant collector emitter voltage VCE . It is given by, DVBE ri = D IB V CE = Constant
2. As the input to a transistor in the CE configuration is between the base-to-emitter junction, the CE input characteristics resembles a family of forward biased diode curves. 3. After the cut-in voltage, the base current (I B ) increases rapidly with small increase in base-emitter voltage (VBE ). Thus the dynamic input resistance is small in CE configuration. 4. For a fixed value of VBE , I B decreases as VCE is increased. 5. Voltages VBE and VCE are positive for npn transistor and they are negative for pnp transistor.
Ø Ø
With a neat diagram explain output characteristics of npn transistor in CE-configuration. + VTU : July-06, Aug.-2000, 02, 04, 05, 08, 09, Feb.-03, 04, 08, Jan.-11, Marks 5 Draw the common emitter circuit and sketch the output characteristics, explain active region, cutoff region and saturation region by indicating them on the characteristic curve. + VTU : Jan.-14, Marks 8
1. This characteristics shows the relation between the collector current I C and collector voltage VCE , for various fixed values of I B . This characteristics is often called collector characteristics. A typical family of output characteristics for an n-p-n transistor in CE configuration is shown in Fig. 2.9. TM
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2 - 11
|IC|(mA) Saturation region
Active region
80
|IB| = 80 mA DIC
DVCE
|IB| = 60 mA
60
Collector current
Bipolar Junction Transistor
a DIC = 20 mA 40
|IB| = 40 mA
DIB = 20 mA |IB| = 20 mA
Note : While plotting output characteristics the magnitudes of voltage and current are considered. Practically the voltage and current polarities are opposite for pnp and npn transistors
20 |IB| = 0 mA 0
0.5
|VCE| (V) 1.5 Cut-off region
1.0
Collector-emitter voltage
Fig. 2.9 Output characteristics of the transistor in CE configuration
2. The value of b dc of the transistor can be found at any point on the characteristics by taking the ratio I C to I B at that point, i.e. b dc = I C / I B . This is known as D.C. beta for the transistor. 3. From the output characteristics, we can see that change in collector-emitter voltage ( DVCE ) causes the little change in the collector current (DI C ) for constant base current I B . Thus the output dynamic resistance is high in CE configuration. D VCE ro = D I C I = Constant OR D I = 0 B
B
4. The output characteristics of common emitter configuration consists of three regions : Active, Saturation and Cut-off. 5. Active Region : n For the operation in the active region, the emitter-base junction (JE) is forward biased while collector base junction (JC) is reverse biased. The collector current rise more sharply with increasing VCE in the linear region of output characteristics of CE transistor. 6. Saturation Region : n In this region, the emitter-base junction (JE) and collector base junction (JC) both are forward biased. n
The saturation value of VCE , designated VCE (sat ) , usually ranges between 0.1 V to 0.3 V. 7. Cut-off Region : The region below I B = 0 is the cut-off region of operation for the transistor. In this region, both the junctions of the transistor are reverse biased. n
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For saturation : IB >
Bipolar Junction Transistor
IC b dc
For active region : VCE > VCE (sat)
Ø
Compare CB, CE and CC transistor configurations.
Ø
Write the special features of transistors in CE mode.
+
VTU : Mar.-01, Aug.-01, Marks 10
Sr.No.
Characteristic
Common Base
Common Emitter
Common Collector
1.
Input resistance (Ri)
Very low (20 W)
Low (1kW)
High (500 kW)
2.
Output resistance (Ro)
Very high (1 MW)
High (40 kW)
Low (50 W)
3.
Input current
IE
IB
IB
4.
Output current
IC
IC
IE
5.
Input voltage applied between
Emitter and Base
Base and Emitter
Base and Collector
6.
Output voltage taken between
Collector and Base
Collector and Emitter
Emitter and Collector
7.
Current amplification factor
8.
Current gain (Ai)
Less than unity
High (20 to few hundreds)
High (20 to few hundreds)
9.
Voltage gain (Av)
Medium
Medium
Less than unity
10.
Applications
a =
IC IE
b=
IC IB
g=
IE IB
As a input stage of Provides both voltage For impedance matching multistage amplifier and current gain greater than unity and hence it is widely used in audio signal amplification
Table 2.1 Comparison of CB, CE, CC configurations
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Bipolar Junction Transistor
Important Examples Example 2.1 For a certain transistor, 99.6% of the carriers injected into the base cross the
collector-base junction. If the leakage current is 5 mA and the collector current is 20 mA, calculate : i) The value of a ii) The emitter current. Solution :
I C(INJ) =
+
VTU : Jan-14, Marks 4
99.6 I E 100
I C(INJ) + I CBO = I C \
99.6 I E + 5 ´ 10 – 6 = 20 ´ 10 –3 100
\
0.996 I E + 5 ´ 10 –6 = 20 ´ 10 –3 i)
IE =
20 ´ 10 –3 – 5 ´ 10 – 6 = 20.07 mA 0.996
ii)
a =
IC 20 mA = 0.996 = IE 20.07 mA
Example 2.2 A transistor has I B = 100 mA and I C = 2 mA. Find
i) b of the transistor, ii) a of the transistor, iii) Emitter current I E , iv) If I B changes by + 25 mA and I C changes by + 0.6 mA find the new value of b .
+
Solution : Given : I B = 100 mA
and I C = 2 mA
i)
b =
IC 2 mA = = 20 IB 100 mA
ii)
a =
b 20 = = 0.952 1 + b 1 + 20
iii) iv)
I E = I B + I C = 100 mA + 2 mA = 2.1 mA New I B = 100 mA + 25 mA = 125 mA New I C = 2 mA + 0.6 mA = 2.6 mA
\
New b =
2.6 mA = 20.8 125 mA
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VTU : July-06, Marks 10
Basic Electronics
2 - 14
Bipolar Junction Transistor
Example 2.3 A transistor has a = 0.9. If IE = 10 mA, find the values of b, g, IB and IC.
+
VTU : Aug.-02, Marks 5
Solution : b
=
0.9 a =9 = 1 -a 1 -0.9
g = 1 + b = 10 IC = a IE = 0.9 ´ 10 mA = 9 mA IB = IE – IC = 10 mA – 9 mA = 1 mA
Multiple Choice Questions with Answers BJT Operation Q.1
In a transistor the current conduction is due to _______ carriers. (a) majority
(b) minority
(c) both a) and b)
(d) none of these (Ans. : c)
+
Q.2
The transistor means ____. (a) transfer-resistor
Q.3
(b) bipolar
(c) multipolar
(Ans. : b)
Fig. 2.10
(b) npn
(c) field effect
(Ans. : a)
(b) pnp, npn
(c) npp, ppn
(d) nnp,pnp (Ans. : b)
The process by which impurities are added to a pure semiconductor is ____ . (a) diffusing
Q.7
(Ans. : a)
List the types of bipolar junction transistors. (a) ppn, npn
Q.6
(c) tri-resistor
The Fig. 2.10 shows the symbol of a ____ transistor. (a) pnp
Q.5
(b) trans-resistor
Transistor is a ____ junction transistor. (a) unipolar
Q.4
(b) drift
(c) doping
Fig. 2.11 shows the equivalent circuit of the ____ transistor. (a) pnp
(b) npn
(d) mixing
C
(c) unijunction
The arrow in the transistor symbol indicates ____ terminal. (a) base
Q.9
(Ans. : c)
E
(Ans. : a)
Q.8
VTU : Jan.-11
(b) collector
B
Fig. 2.11
(c) emitter (Ans. : c)
The arrow in the transistor symbol indicates the direction of ____. (a) conventional emitter current
(b) electron current in emitter
(c) supply current
(d) ans (a) and (b) TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
(Ans. : a)
Basic Electronics
Q.10
2 - 15
Base of the transistor is always ____ and ___ doped. (a) thick, lightly
Q.11
(b) thin, lightly
(c) thin, heavily
(Ans. : b)
(c) lightly
(Ans. : a)
The collector of a transistor is _____ doped. (a) heavily
Q.12
Bipolar Junction Transistor
(b) moderately
In transistors the collector region is larger than the emitter region for ____. (a) better heat dissipation
(b) higher value of b
(c) better amplification
Q.13
The ________region has highest thickness than all other regions in a BJT. (a) base
Q.14
(b) collector
(b) base
(c) lightly
(b) collector region
(b) holes
(c) base region
(d) all of the above (Ans. : a)
(c) both electrons and holes
(Ans. : c)
______ of electrons and holes in the base region constitutes the base current. (b) Recombinations
(c) Thermal agitation
(Ans. : b)
The largest current flow of a bipolar transistor occurs ________ . (a) in the emitter
(b) in the base
(c) in the collector
(d) through the collector base
Q.20
(Ans. : c)
The conduction in BJT is because of ___________.
(a) Ionization
Q.19
(Ans. : b)
Doping concentration is highest in __________ and BJT.
(a) electrons
Q.18
(c) emitter
(b) moderately
(a) emitter region
Q.17
(Ans. : b)
The depletion region at collector junction in an unbiased transistor extends more into the base region because it is ____ doped. (a) heavily
Q.16
(c) emitter
The depletion region at emitter junction in an unbiased transistor extends more into the____ region. (a) collector
Q.15
(Ans. : a)
(e) through the emitter collector
(Ans. : a)
A transistor ___________. (a) is similar to a relay in that it uses a small amount of current to control a larger amount of current flow. (b) has three connections called the base, emitter and collector. (c) is like a switch in that it is used to turn a circuit on and off. (d) all of the above.
Q.21
The BJT is a ________ controlled device. (a) current
Q.22
(Ans. : d)
(b) voltage
(c) field
(Ans. : a)
(c) input resistance
(Ans. : b)
In BJT output current is controlled by _____ . (a) input voltage
(b) input current
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Q.23
2 - 16
Bipolar Junction Transistor
In a transistor the part heavily doped is ________. (a) emitter
(b) base
(c) collector
(d) all are equally doped (Ans. : a)
+
VTU : Aug.-09
BJT Voltages and Currents Q.1
In a reverse biased collector junction IC = _______ when the emitter is left open. (a) 0
Q.2
(c) I CBO
(b) I E
The _____ carriers constitute current I CBO . (a) both minority and majority
Q.3
(b) 200 mA
Q.7
bdc = _______.
(a) 50 to 300
(b) 500 to 1000 (b) I C / I E
(a) I B / I E
(c) 1.8 mA
(Ans. : b)
(c) more than 1000
(Ans. : a)
(c) I C / I B
(d) None of the above (Ans. : c)
(b) I C and I B
(c) I E and I B
(d) None of the above (Ans. : b)
The b in terms of a is given by ________. (a) b =
a (1+ a )
(b) b =
a 1- a
(c) b =
1+ a a
(Ans. : b)
b in a transistor when I B = 105 mA, I C = 2.05 mA is _________. (a) 11.5
(b) 17.5
(c) 13.5
(b) I C / I E
(c) I C / I B
(d) 19.5
(Ans. : d)
What is a equal to ? (a) I B / I E
Q.12
(Ans. : b)
The ratio of which two currents is represented by b ? (a) I C and I E
Q.11
(c) greater than unity
(b) 20 mA
Typically the value of b dc is ________.
Q.10
(d) 20.2 mA (Ans. : c)
For a certain transistor a dc = 0.99 and I E = 2 mA. Calculate I B.
Q.6
Q.9
(c) 200 mA
(b) less than unity
(a) 1.96 mA
Q.8
(c) majority (Ans. : b)
The value of a dc is always ________. (a) unity
Q.5
(b) minority
For a properly biased pnp transistor, let IC = 10 mA and IE = 10.2 mA. What is the level of IB ? (a) 0.2 A
Q.4
(Ans. : c)
(d) None of the above (Ans. : b)
Determine the value of a when b = 100. (a) 1.01
(b) 101
(c) 0.99
(d) Cannot be solved with the information provided
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(Ans. : c)
Basic Electronics
Q.13
2 - 17
Bipolar Junction Transistor
The I CEO in terms of ICBO is given by _____. (a) I CEO = (1 + b) I CBO (b) I CEO = b I CBO + 1 (c) I CEO = I CBO (1 + b)
Q.14
The typical value of VBE (cut -off) for a Si transistor is ______. (a) 0.7 V
Q.15
(c) 0.7 mV
(d) Undefined (Ans. : b)
(b) 0.6
(c) 0.7
(Ans. : a)
(b) 0.2 V
(c) 0.9 V
(Ans. : a)
(b) VCE
(c) VBC
(d) None of the above (Ans. : c)
The relation between a and b is given by ________ . (a) a = b
Q.20
(b) 0.7 V
Which of the following voltages must have a negative level (value) in any npn circuit ? (a) VBE
Q.19
(Ans. : b)
The typical value of V BE (sat) in CE configuration for a silicon transistor is _____. (a) 0.8 V
Q.18
(c) 0.3 V
The value of V BE (active) for a Ge transistor is _____ V. (a) 0.2
Q.17
(b) 0 V
How much is the base-to-emitter voltage of a transistor in the "active" state ? (a) 0 V
Q.16
(Ans. : a)
(b) a =
b 1- b
(c) a =
b 1+ b
(d) a =
+
1 . b
(Ans. : c)
VTU : Aug.-09
a of a transistor is 0.99. Calculate b. (a) b = 0.9
(b) b = 90
(c) b = 99
(d) b = 0.09 (Ans. : c)
+
VTU : Jan.-14
BJT Amplification Q.1
The output voltage of an amplifier is 5 V when an input voltage is 50 mV. Its voltage gain is _____. (a) 100
(b) 250
(c) 1000
(Ans. : a)
Common Base Characteristics Q.1
The transistor acts as an amplifier in the _____ region . (a) cut-off
Q.2
(c) saturation
(Ans. : b)
The dynamic output resistance of transistor in CB configuration is _______at constant I E. (a) D VEB D I E
Q.3
(b) active (b) D VEB D IC
(c) D VCB D IC
(Ans. : c)
a ac is the slope of _____ characteristics of transistor in CB configuration. (a) input
(b) output
(c) transfer
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(Ans. : c)
Basic Electronics
Q.4
(b) I E , I C
(c) VEB , I E
(Ans. : b)
(b) V CE @ 0
(c) VCE = 5 V
(d) VCE = VCC + VBE (Ans. : b)
(b) cut-off
(c) active
(Ans. : c)
In _______ configurations there is phase shift of 0º between input and output. (a) CB
Q.9
(Ans. : a)
In _________ region the collector current is proportional to the base current. (a) saturation
Q.8
(c) I B and I E
In the saturation region of the BJT _________. (a) VCE = VCC
Q.7
(b) I C and I B
The transfer characteristics of a CB configuration is a graph of ______. (a) VCB , I C
Q.6
Bipolar Junction Transistor
The transfer characteristics of CB shows the relation between _____. (a) I C and I E
Q.5
2 - 18
(b) CE
(c) CC
(d) CB and CC (Ans. : d)
In saturation region the collector current ___________. (a) is independent of I B (b) is proportional to I B (c) is equal to I B
Q.10
For operating in the active region, the emitter junction should be ____ biased and collector junction should be ____ biased. (a) forward, forward
Q.11
Q.14
Q.15
(c) forward, reverse
(d) reverse, forward (Ans. : c)
(b) reverse
(c) zero
(Ans. : a)
In which region are both the collector-base and base-emitter junctions forward biased ? (a) Active
Q.13
(b) reverse, reverse
The emitter junction is ____ biased for operation in saturation region. (a) forward
Q.12
(Ans. : a)
(b) Cut-off
(c) Saturation
(d) All of the above (Ans. : c)
For the BJT to operate in the saturation region, the base-emitter junction must be _____ biased and the base-collector junction must be ______ - biased. (a) forward, forward
(b) forward, reverse
(c) reverse, reverse
(d) reverse, forward
(Ans. : a)
At what region of operation is the base-emitter junction forward biased and the base-collector junction reverse biased ? (a) Saturation
(b) Linear or active
(c) Cut-off
(d) None of the above
(Ans. : b)
Which of the statement(s) for the Base-Emitter (B-E) and the Collector-Base (C-B) junctions is/are true ? (a) IC is independent of VCE in the active region. IC = 0 and VCE = VCC in the cut-off region. IC = IC (sat) and VCE = 0 in the saturation region. (b) The B-E should be forward-biased and the C-B should be reverse-biased in the active region.
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Bipolar Junction Transistor
(c) The base current I B controls the collector current IC in the active, cut-off and saturation regions. (d) All of the above.
(Ans. : b)
Common Emitter Characteristics Q.1
Which of the following regions is (are) part of the output characteristics of a transistor ? (a) Active
Q.2
(b) base, collector
Q.13
(Ans. : c)
(c) collector, emitter
(b) I C, V EC
(Ans. : a)
(c) VCE , I C
(b) I CEO
(Ans. : c)
(c) 0
(b) ICBO
(Ans. : b)
(c) ICO
(b) a dc
(Ans. : a)
(c) g dc
(b) high
(Ans. : a)
(c) moderate
(b) 99 mA
(c) 198 mA
(Ans. : a) (d) 200 mA (Ans. : d)
For a BJT, under the saturation condition _________. (a) I C = b I B
Q.12
(d) ³
I CEO in a BJT ( a = 0.99), I CO = I CBO = 2 mA is _________. (a) 2 mA
Q.11
(c) £
The value of dynamic output resistance in the CE configuration is _____ that in CB configuration. (a) low
Q.10
(b) <
The current gain of CE configuration is ______. (a) b dc
Q.9
(Ans. : c)
The reverse saturation current of CE configuration with base open is _____. (a) ICEO
Q.8
(d) ³
For CE configuration, in the cut-off region, I C = ____. (a) I CBO
Q.7
(c) £
The output characteristics of a CE configuration is the graph of _______. (a) VCE , VEC
Q.6
(b) <
I CBO flows from _____ to _____ when emitter is open. (a) collector, base
Q.5
(d) All of the above (Ans. : d)
The saturation region if defined by VCE ______ VCE sat. (a) >
Q.4
(c) Saturation
The cut-off region is defined by I B ______ 0 A. (a) >
Q.3
(b) Cut-off
(b) I C > b I B
(c) IC is independent of all other parameters (d) IC < b I B (Ans. : d) When a transistor is operated with the emitter diode forward biased and the collector diode reverse biased, the collector current will be _________. (a) almost zero
(b) almost equal to the emitter current
(c) infinitely high
(d) many times more than the emitter current
(Ans. : b)
In CE configuration, when collector current is zero, VCE equals ________ . (a)
VCC RC + RE
(b) VCC
(c)
TM
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(d)
VCC . RE
+
(Ans. : b)
VTU : Aug.-09
Basic Electronics
Q.14
2 - 20
The input resistance of CE configuration is D VBE D I B at constant ______. (b) VCB
(a) VCE
Q.15
(c) I C
(Ans. : a)
A transistor is in saturation if _______. (a) I B >
Q.16
Bipolar Junction Transistor
IC b
(b)
IC > IB b
(c) I C = b I B
(Ans. : a)
An amplifier is generally connected in ______ mode. (a) saturation
(b) cut-off
(c) active
(d) short
+
(Ans. : c)
VTU : July-11
Common Collector Characteristics Q.1
g = ________ (b) I E I C
(a) I C I B
Q.2
(b) CE
(b) CC
(c) CE
(d) all of the above (Ans. : b)
(b) CE
(c) CC
(d) CB and CC (Ans. : d)
The phase difference between input and output of an emitter follower is _______. (a) in-phase
Q.6
(Ans. : c)
In _______ configurations there is phase shift of 0º between input and output. (a) CB
Q.5
(c) CC
The output signal has approximately the same amplitude and phase as the input signal in __________. (a) CB
Q.4
(Ans. : c)
The ____ configuration is also called emitter follower. (a) CB
Q.3
(c) I E I B
(b) out-of-phase
(c) 90º
(d) 45º
+
(Ans. : a)
VTU : July-11
Which of the following is (are) related to an emitter-follower configuration ? (a) The input and output signals are in phase. (b) The voltage gain is slightly less than 1. (c) Output is drawn from the emitter terminal. (d) All of the above.
(Ans. : d)
Comparison of CB, CE, CC Configurations Q.1
The _______ configuration is the most widely used. (a) CB
Q.2
(b) CE
(c) CC
(Ans. : b)
The _____ configuration is used as a input stage. (a) CB
(b) CE
(c) CC
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(Ans. : a)
Basic Electronics
Q.3
2 - 21
The input resistance of CC configuration is _____. (a) very low
Q.4
(b) low (b) higher than
(b) CE
Q.12
Q.15
Q.17
(Ans. : c)
(c) CC
(Ans. : c)
______ amplifier configuration provides both high current and voltage gain. (b) CE
(c) CC
(Ans. : b)
As compared to a CB amplifier, a CE amplifier has __________. (a) lower current amplification
b) higher current amplification
(c) lower input resistance
(d) higher input resistance
(Ans. : b)
In _______ configuration there is phase shift of 180º between input and output. (b) CE
(c) CC
(Ans. : b)
____ transistor configuration provides the highest input impedance. (b) CE
(c) CC
(Ans. : c)
Which of the following is (are) the application (s) of a transistor ? (a) Amplification of signal
(b) Switching and control
(c) Computer logic circuitry
(d) All of the above
(Ans. : d)
A _____ configuration does not need the thermal stabilization. (b) CE
(c) CC
(Ans. : a)
Which of the following configurations can a transistor set up ? (a) Common-base
(b) Common-emitter
(c) Common-collector
(d) All of the above
(Ans. : d)
The______ configuration is used as an output stage. (a) CB
Q.18
(c) voltage gain
(b) CE
(a) CB
Q.16
(Ans. : a)
Identify which configuration has following characteristics. Voltage gain < 1, Input impedance high and output impedance very low.
(a) CB
Q.14
(Ans. : a)
(c) high
(b) current gain
(a) CB
Q.13
(c) CC
(b) low
(a) CB
Q.11
(Ans. : c)
The _____ of CC configuration is less than unity.
(a) CB
Q.10
(c) CC
The output resistance of CC configuration is _______.
(a) input resistance
Q.9
(Ans. : b)
Current gain of transistor amplifier is lowest in _____ configuration.
(a) very low
Q.8
(c) same as
(b) CE
(a) CB
Q.7
(Ans. : c)
Transistor has lowest output impedance in ____ configuration. (a) CB
Q.6
(c) high
The value of input resistance in the CE configuration is _____ that in CB configuration. (a) lower than
Q.5
Bipolar Junction Transistor
(b) CE
(c) CC
(Ans. : c)
The _____ transistor has the highest power gain. (a) CE
(b) CC
(c) CB
(d) None of these (Ans. : b)
+
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Basic Electronics
Q.19
Q.20
Q.21
Bipolar Junction Transistor
For an emitter follower, the voltage gain is ________. (a) unity
(b) greater than unity
(c) less than unity
(d) zero
+
(Ans. : c)
VTU : Jan.-11
Emitter follower is a ____. (a) voltage amplifier
(b) current amplifier
(c) attenuator
(d) none of these
+
(Ans. : b)
VTU : July-11
Emitter follower has an input of 1 volt, then its output voltage is ____. (a) 0.5 V
Q.22
2 - 22
(b) 10 V
(c) 1 V
The _____ transistor is used for impedance matching. (a) CB
(b) CE
(c) CC
(d) 5 V
+
(Ans. : a)
VTU : July-11
(d) None of these (Ans. : c)
+
VTU : Jan.-11, 14
qqq
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3
BJT Biasing
Chapter at a Glance Important Definitions 1. Quiescent points / Operating points : For different values of IB, we have different intersection points of the output curve and the dc load line. This points are called quiescent points or operating points. 2. Define biasing of transistor : In order to operate transistor in the desired region we have to apply external dc voltages of correct polarity and magnitude to the two junctions of the transistor. This is nothing but the biasing of the transistor.
Important Formulae 1. For Fixed Bias Circuit VCC - VBE IB = RB VCE = VCC - I C R C 2. For Collector - Base Bias Circuit VCC - VBE IB = R B + (1 + b) R C VCE = VCC -(I B + I C ) R C 3. For Voltage Divider Bias VT - VBE IB = R B + (1 + b) R E
Where
VT =
R2 V R 1 + R 2 CC
VCE = VCC - I C R C - I E R E
Important Questions and Answers
Ø Ø
+
Give the concept of d.c. load line.
VTU : Aug.-02, Marks 4
Explain the d.c. load line and operating point, with example, related to the transistor. + VTU : Jan.-11, Marks 4 (3 - 1) TM
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Basic Electronics
3-2
BJT Biasing
· For different values of IB, we have different intersection points of the output curve and the dc load line. This points P, Q and R are called quiescent points or operating points.
Ø
Explain the effect of emitter resistance on dc load line.
· In Fig. 3.1 (a) the emitter resistance (RE) is connected in series with the transistor and supply voltage (VCC) is directly connected to the collector terminal. Thus, here RE is d.c. load. · Applying KVL to the collector circuit of Fig. 3.1 (a) we have. VCC – VCE – IERE = 0 \
VCE = VCC – IERE
· In Fig. 3.1 (b) collector resistance (RC) and emitter resistance (RE) both are present. +VCC
· Applying KVL to the collector circuit of
IC
Fig. 3.1 (b) we have, VCC – ICRC – VCE – IERE = 0 \
C
VCE = VCC – ICRC – IERE
B
VCE = VCC – IC(RC + RE) Q IC » IE
· On the d.c. load line at VCE = 0, the value of IC in absence of RE will be V IC = CC RC where as in presence of RE, this value will be IC
Ø
+ VCE
E
– +
RC C – +
B
VCE – E +
IE RE
IE
–
(a) RE = RL(dc)
VCC = RC + RE
+VCC +
RE –
(b) (RC+RE) = RL(dc)
Fig. 3.1
State the techniques used to stabilize operating point.
· The operating point of transistor varies due to change in temperature. To maintain the operating point stable by keeping I C and VCE constant so that the transistor will always work in active region, the following techniques are normally used. n
Stabilization techniques : Stabilization techniques refer to the use of resistive biasing circuits which allow I B to vary so as to keep I C relatively constant with variations in I CO , b , and VBE .
n
Compensation techniques : Compensation techniques refer to the use of temperature-sensitive devices such as diodes, transistors, thermistors, etc., which provide compensating voltages and currents to maintain the operating point stable.
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Basic Electronics
Ø Ø
3-3
BJT Biasing
+
Explain collector-base bias circuit.
VTU : Feb.-07, Marks 8
With a neat circuit diagram, explain the working of an collector-to-base bias circuit using an npn transistor and derive the equation for IB. + VTU : Jan.-14, Marks 6
· The Fig. 3.2 shows the dc bias with voltage feedback. It is called the collector to base bias circuit. · It is an improvement fixed-bias method.
over
+VCC IC + IB
RC
the
RB IB
· In this the biasing resistor is connected between the collector and the base of the transistor to provide a feedback path. Thus I B flows through R B and (I C + I B ) flows through the R C .
Vi
B
Vo
+
VBE
–
E
VCE
Fig. 3.2 DC bias with voltage feedback
· Applying voltage law to the base circuit we get, VCC – (I B + I C ) R C - I B R B – VBE = 0 \
VCC = (R B + R C ) I B + I C R C + VBE = (R B + R C ) I B + bI B R C + VBE IB = IB =
VCC – VBE R B + (1+ b ) R C VCC – VBE RB + b RC
Q b >> 1
· Note that the only difference between the equation for I B and that obtained for the fixed bias configuration is the term bR C . Thus we can say that the feedback path results in a reflection of the resistance R C to the input circuit.
· Applying Kirchhoff’s voltage law to the collector circuit we get, VCC – (I C + I B ) R C – VCE = 0 \
VCE = VCC – (I C + I B ) R C
· If there is a change in b due to piece to piece variation between transistors or if there is a change in b and I CO due to the change in temperature, then collector current I C tends to increase, since I C = b I B + I CEO .
· As a result, voltage drop across R C increases. Since supply voltage VCC is constant, due to increase in I C R C , VCE decreases. Due to reduction in VCE , I B reduces.
· As I C depends on I B , decrease in I B reduces the original increase in I C . The result is that the circuit tends to maintain a stable value of collector current, keeping the Q point fixed. TM
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Basic Electronics
3-4
BJT Biasing
· In this circuit, R B appears directly across input (base) and output (collector). A part of the output is fed back to the input, and increase in collector current decreases the base current. Thus negative feedback exists in the circuit, so this circuit is also called voltage feedback bias circuit.
Ø
Explain with neat circuit the operation of voltage divider bias circuit. + VTU : Feb.-08, Marks 8; Jan.-11, July-11, Marks 4
· Fig. 3.3 shows the voltage divider bias circuit. In this circuit, the biasing is provided by three resistors : R 1 , R 2 and RE . · The resistors R 1 and R 2
VCC
R1
act as a
I + IB
RC
IC Vo
potential divider giving a fixed voltage to point B which is base.
IB
Vi
VCE
+
· If collector current increases due to change in temperature or change in b, the emitter current I E also increases and the voltage drop across R E increases, reducing the voltage difference between base and emitter (VBE ).
VBE
R2
· Due to reduction in VBE , base current I B
–
I
RE
IE
Fig. 3.3 Voltage divider bias circuit
and hence collector current IC also reduces. Therefore, we can say that negative feedback exists in the emitter bias circuit.
+VCC RC
IC
RE
IE
· This reduction in collector current I C compensates for the original change in I C .
RB = R1 || R2
· Fig. 3.4 shows simplified circuit of voltage divider bias. Here, R 1 and R 2 are replaced by R B and VT , where R B is the parallel combination of R 1 and R 2 and VT is the Thevenin’s voltage. R B can be calculated as VCC R 2 R1 R 2 ... (3.1) RB = VT = R1 + R2 R1 + R 2
IB VT
VBE
Fig. 3.4 Thevenin's equivalent circuit for voltage divider bias
Applying KVL to the base circuit of Fig. 3.4 we get, VT = I B R B + VBE + I E R E
... (3.2)
= IBRB + VBE + (1 + b) IBRE \
IB =
VT - VBE R B + (1 + b)R E
…(3.3) TM
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Basic Electronics
3-5
BJT Biasing
Applying KVL to the collector circuit we get, VCC – ICRC – VCE – IERE = 0 \
Ø Ø
VCE = VCC – ICRC – IERE
…(3.4)
+
Give the comparison between various biasing circuits.
VTU : Aug.-08
Compare base bias, collector to base bias and voltage divider bias with regard to stability of the transistor collector voltage with spread in h FE value. + VTU : Feb.-10, Marks 10
· We have seen that the biasing circuit should provide the stability of Q point against the change in device parameters.
· The VCE values calculated for each circuit for h FE ( min ) and h FE ( max ) are listed in Table 3.1. Each circuit uses 12 V supply and has 2 kW collector (load) resistance. On the basis of these similarities if we compare VCE values of these circuits. We can observe following points.
· The collector to base bias provides more stability than the base bias circuit. · Voltage divider bias provides the greatest stability against h FE variations. Because of its excellent stability, voltage divider bias is the most commonly used biasing circuit. Biasing circuits
Base bias
Collector to base bias
Voltage divider bias
VCE (min )
3V
6.932 V
5.26 V
VCE (max )
4.466 V
7.426 V
5.276 V
Table 3.1 VCE minimum and maximum values for similar bias circuits
The Table 3.2 gives the comparison between the biasing circuits. Parameter
Base bias
Collector to base bias VCC
VCC
Circuit
RB
Voltage divider bias
RB
RC
VCC
RC
(IC+IB)
R1
IB
IC
RC
I1
IC
IB
IB R2
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IE RE
Basic Electronics
3-6
Stability provided
Less
Feedback
No
Applications
BJT Biasing
Medium
Highest
Voltage shunt negative feedback
Used in circuits where stability is not the important criteria.
Voltage shunt feedback from the collector prevents. It is used in switching circuits.
Current series negative feedback It is most preferred biasing circuit the transistor from going into saturation. It is used in circuits where stability requirements are moderate.
Table 3.2 Comparison of basic biasing circuits
Important Examples Example 3.1
Determine the operating point for a silicon transistor biased by base bias method
with b = 100, RB = 500 kW, RC = 2.5 KW and VCC = 20 V. Also draw the load line.
+
VTU : Jan.14, Marks 6 +VCC = 20 V
Solution : Apply KVL to base circuit – IBRB – VBE + VCC = 0 \ Q
IB
IB
V – VBE 20 – 0.7 = CC = = 38.6 mA RB 500 ´ 10 3
IC = bI B = 100 ´ 38.6 ´ 10 – 6 = 3.86 mA
RB = 500 kW
\ ICQ = 3.86 mA – ICRC – VCE + VCC = 0 \ VCE = VCC – ICRC = 20 – (3.86 ´ 10 –3 ´ 2.5 ´ 10 3 ) = 10.35 V
To get two points on the load line, \
VCE = VCC, IC = 0 A(20 V, 0)
ii) \
+
–
–
VCE = 0, IC =
VBE = 0.7 V –
Fig. 3.5 (a)
VCEQ = 10.35 V
i)
+
+
Apply KVL to collector circuit
\
IC
VCC 20 = 8 mA = RC 2.5 ´ 10 3
B (0, 8 mA)
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RC = 2.5 kW
+ VCE –
Basic Electronics
3-7
BJT Biasing
The operating point is (10.35 V, 3.86 mA) IC (mA) 8 B 7 6
DC load line
5 4
Q(10.35 V, 3.86 mA)
3 2 1 A 0
5
10
15
20
25 VCE (V)
Fig. 3.5 (b) Example 3.2 The fixed biased circuit in
VCC= 12 V
Fig. 3.6 is subjected to an increase in junction temperature from 25 ° C to 75 ° C.
RB 100 kW
If b = 100 at 25 º C and b = 125 at 75 º C,
IB
RC 600 W
determine percent change in Q point values (VCE , I C )
over
the
temperature
IC Si
range.
Neglect any change in VBE . Fig. 3.6
Solution : At 25 ° C : Applying KVL to the base circuit we get, VCC – I B R B – VBE = 0 IB =
VCC – VBE 12 – 0.7 = 113 mA = RB 100 ´ 10 3
I C = b I B = 100 ´ 113 ´ 10 –6 = 11.3 mA
\
Applying KVL to the collector circuit we get VCC – I C R C – VCE = 0 TM
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Basic Electronics
3-8
BJT Biasing
VCE = VCC – I C R C = 12 – 11.3 ´ 10 –3 ´ 600 = 5.22 V
\ At 75 ° C : Since b = 125,
IC VCE
= b I B = 125 ´ 113 ´ 10 –6 = 14.125 mA =
VCC – I C R C = 12 – 14.125 ´ 10 –3 ´ 600
= 3.525 V The percent change in I C is % ¶ IC = =
I C (75° C) – I C (25 ° C) 14.25 ´ 10 – 3 – 11.3 ´ 10 – 3 ´ 100 % = ´ 100 % I C (25° C) 11.3 ´ 10 – 3
25 % (an increase)
The percent change in VCE is VCE (75° C) – VCE (25 ° C) 3.525 – 5.22 % ¶ VCE = ´ 100 % = ´ 100 % VCE (25° C) 5.22 = – 32.47 % (a decrease) Example 3.3 Calculate the minimum and maximum values of I C and VCE for the base bias when
hFE ( min ) = 50 and hFE ( max ) = 60. For circuit, VCC = 12 V, RC = 2 K and R B = 150 K. Assume silicon transistor. Solution : For silicon transistor VBE = 0.7 V \
IB =
VCC - VBE 12 V - 0.7 V = = 75.33 mA RB 150 k W
For h FE ( min ) I C = h FE ( min ) ´ I B = 50 ´ 75.33 mA = 3.767 mA and
VCE = VCC - I C R C = 12 - 3.767 mA ´ 2 kW = 4.466 V
For h FE ( max ) I C = h FE ( max ) ´ I B = 60 ´ 75.33 mA = 4.52 mA and
VCE = VCC - I C R C = 12 - 4.52 mA ´2 kW = 3 V
Example 3.4 For the circuit shown in Fig 3.7 Compute i) Three transistor currents ii) Voltage
+
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Basic Electronics
3-9
BJT Biasing
VCC = 12 V RC
100 W
RB = 12 kW IC b = 120 IE
Fig. 3.7
Solution : i) Applying KVL to the base circuit we have, VCC - (I B + I C )R C - I B R B - VBE = 0 \
IB =
VCC - VBE 12 - 0.7 = = 468.88 mA (1 + b) R C + R B (1 + 120) 100 + 12 ´ 10 3
IC = b´ I B = 120 ´ 468.88 mA = 56.2656 mA IE = IB +IC = 56.7344 mA ii) Drop across RC = (IB + IC) RC = 56.7344 ´ 10 -3 ´ 100 = 5.67344 V Drop across RB = IB RB = 468.88 ´ 10 - 6 ´ 12 ´ 10 3 = 5.62656 V Example 3.5 For the circuit shown in Fig. 3.8 b = 100 for the silicon transistor. Calculate VCE
+
and I C . TM
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Basic Electronics
3 - 10
BJT Biasing
+10 V
R1 = 10 kW
R C = 1 kW C2
Vi
Vo
C1 R2 = 5 kW
RE = 470 W
CE
Fig. 3.8
Solution : Since (1 + b) R E = 47470 < 10R 2 = 50000 We use exact analysis VT =
R2 5 ´ 103 VCC = ´ 10 = 3.33 V R1 + R 2 10 ´ 10 3 + 5 ´ 10 3
RB =
10 ´ 5 = 3.33 kW 10 + 5
Applying KVL to the base circuit we get,
\
VT - I B R B - VBE - (1 + b) I B R E = 0 VT - VBE 3.33 - 0.7 = = 51.77 mA IB = R B + (1 + b) R E 3.33 ´ 10 3 + (101) 470 I C = bI B = 100 ´ 51.77 mA = 5.177 mA IE = IC +IB
= 5.23 mA Applying KVL to collector circuit we get, VCE = VCC - I C R C - I E R E = 10 - 5.177 ´ 1 - 5.23 ´ 0.47 = 2.365 V Example 3.6 Draw the d.c. load line for the voltage-divider biasing circuit shown in Fig. 3.9.
+
Find the collector current and the Q point.
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Basic Electronics
3 - 11
BJT Biasing +VCC = 30 V
3 kW
6.8 kW
1 kW
750 kW
Fig. 3.9
Solution : The various voltages and currents are shown in the Fig. 3.10 (a). + 30 V VCC = 30 V 6.8 kW
1 kW
R1
R2
RC
RC
3 kW IB
VT RE
750 W
IC
RB
+ –
(b)
1 ´ 10 3 ´ 6.8 ´ 10 3
1 ´ 10 3 + 6.8 ´ 10 3 Applying KVL to the base circuit we have,
IB =
and
750 W IE
The Thevenin's equivalent is shown in the Fig. 3.10 (a). R2 30 ´ 1 ´ 10 3 = 3.8461 V VT = VCC ´ = R1 + R2 1 ´ 10 3 + 6.8 ´ 10 3
- I B R B - VBE - I E R E + VT = 0 Let b = 100
–
– RE
Fig. 3.10
= 871.7948 W
I E = (1 + b) I B
VT - VBE 3.8461 - 0.7 = R B + (1 + b) R E 871.7948 + (1 + 100) ´ 750
\
I B = 41.06 mA,
\
I C = b ´ I B = 100 ´ 41.06 ´ 10 - 6 = 4.106 mA
I E = 4.14 mA
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+ VCE
+ VBE
(a)
R B = R 1|| R 2 =
3 kW
Basic Electronics
3 - 12
BJT Biasing
Applying KVL to collector loop we have, - 3 ´ 10 3 I C - VCE - 750 ´ I E + 30 = 0 \
VCE = 30 - 3 ´ 10 3 ´ 4.106 ´ 10 - 3 - 750 ´ 4.14 ´ 10 - 3 = 14.577 V
For drawing the d.c. load line, For I C = 0,
VCE = VCC = 30 V
For VCE = 0,
IC =
VCC 30 = = 8 mA RC + RE 3000 + 750
Hence the load line is shown in the Fig. 10 (c). IC(mA) D.C. load line
8 mA ICQ = 4.106 mA
0
Q
VCEQ 14.577 V
VCE(V)
VCC = 30 V
Fig. 3.10 (c) Example 3.7 Design a collector to base bias circuit to have VCE = 5 V and I C = 5 mA. When
the supply voltage is 15 V and b dc = 100, assume silicon transistor.
+
VTU : Feb.-09, Marks 8
Solution : The circuit is shown in the Fig. 3.11.
+VCC
I C = 5 mA, VCC = 15 V, VCE = 5 V, b = 100 IB
I 5 ´ 10 -3 = C = = 50 mA b 100
RC IB
(I C + I B )R C + VCE = VCC
+ VBE
\ [5 ´ 10 -3 + 50 ´ 10 -3 ]R C + 5 = 15
+ VCE –
–
\ R C = 1.9802 kW Take R C = 2 kW standard value.
Fig. 3.11
Applying KVL base circuit we have, - I B R B - VBE + VCE = 0
... VBE = 0.7 V for Si
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IC + IB
–
RB
Applying KVL to collector circuit we have,
+
Basic Electronics
\
3 - 13
BJT Biasing
-50 ´ 10 -6 R B - 0.7 + 5 = 0
\ Choose
R B = 86 kW R B = 91 kW standard value.
Multiple Choice Questions with Answers DC Load Line and Bias Point Q.1
The Q point is also known as _____. (a) open point
Q.2
(b) operating point
(Ans. : b)
If the transistor is biased to place Q point in the saturation region, it will act as _____. (a) amplifier
Q.3
(c) d.c. point
(b) open switch
(c) closed switch
(Ans. : c)
The slope of a d.c. load line represents ______. (a) collector resistance (b) reciprocal of d.c. load resistance (c) reciprocal of a.c. load resistance
Q.4
(b) unstable (b) VCB , IC
(Ans. : a)
(c) VCE , IC
(Ans. : c)
_____ has an important effect on shifting of the operating point. (a) Voltage
Q.7
(c) bistable
VTU : Jan.-14
The CE configuration, co-ordinates of Q point are _______. (a) VCE , IB
Q.6
+
The position of Q point on the d.c. load line should be ____. (a) stable
Q.5
(Ans. : b)
(b) Change in b
(c) Current
(Ans. : b)
In CE configuration, the _____ half cycle of the output voltage will get distorted if the Q point is near cut-off. (a) positive
(b) negative
(c) none
(Ans. : a)
Q.8
In order to avoid the distortion in the output waveform, the Q point has to be placed _________. VCC (a) near cut-off (b) at the centre of the d.c. load line (c) near saturation RC (Ans. : b)
Q.9
The point of intersection on y-axis with d.c. load line indicates the value of _____. (b) IC = 0
(a) IC (max)
Q.10
(c) IC (sat)
C
(Ans. : a)
Find the value of VCE when VCC = 20 V, RC = 5 kW and I C = 2 mA. (a) 10 (d) 20 V
V
(b)
–10
V
TM
(c)
0.7 V (Ans. : a)
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E
Basic Electronics
Q.11
(c) low, high
(d) high, low (Ans. : c)
(b) active
(c) saturation
(Ans. : b)
(b) saturation
(c) active
(Ans. : b)
(b) VCE and I C
(c) VCC and I C
(Ans. : b)
The transistor turn on and turn off time should be as _____ as possible. (a) long
Q.17
(b) low, low
The power dissipation in the transistor is a product of ______. (a) I C and RC
Q.16
(Ans. : a)
The transistor is operated as a close switch in _____ region. (a) cut-off
Q.15
(c) active
We cannot operate the transistor in ________ region for the switching applications. (a) cut-off
Q.14
(b) saturation
The transistor may be used as a switch so that when it is in the saturated state its on resistance is very ______ or in the cut-off state its off resistance is very ______. (a) high, high
Q.13
BJT Biasing
The transistor is operated as a open switch in _____ region. (a) cut-off
Q.12
3 - 14
(b) small
(Ans. : b)
If the operating point of an npn transistor amplifier is selected in saturation region, it is likely to result in __________. (a) thermal runaway of transistor (b) clipping of output in the positive half of the input signal (c) need for high d.c. collector supply (d) clipping of output in the negative half of the input signal
Q.18
In CE configuration, the upper end of d.c. load line is called the _____ point and the lower end is the ____ point. (a) Q, base
Q.19
(c) saturation, cut-off
(d) cut-off, saturation (Ans. : c)
+
(b) resistance line
(c) Load line
VTU : Jan.-11
(d) Y-axis
(Ans. : c)
The intersection of d.c. load line and the output characteristics of a transistor is called ______. (a) Q-point
Q.21
(b) base, Q
The transistor operating point is along the ____. (a) X-axis
Q.20
(Ans. : b)
(b) quiescent point
(c) operating point
(d) all of these (Ans. : d)
When a transistor is used as a switch, it works in the following region : (a) Active and cut-off (b) Saturation and cut-off (c) Saturation and active
+
(d) None of these
VTU : July-11 (Ans. : b)
Need of Biasing Circuit Q.1
Which of the following factor affects the Q point stability ? (a) Temperature
(b) Bypass capacitors TM
(c) Coupling capacitors
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(Ans. : a)
Basic Electronics
3 - 15
BJT Biasing
Base Bias, Collector to Bias Configuration, Voltage Divider Bias, Comparison of Basic Biasing Circuits Q.1
In self bias or emitter bias circuit ____ is connected between emitter and ground. (a) inductor
Q.2
(b) capacitor
+
(Ans. : b)
Feb.-10
(d) Emitter
+
(Ans. : b)
Aug.-11
The best biasing stability is achieved by using _____ biasing circuit. (a) Fixed
Q.5
(d) none of these
Which transistor bias circuit has poor stability because its Q-point varies with bdc ? (a) Collector feedback (b) Base (c) Voltage divide
Q.4
(Ans. : c)
The self bias arrangement gives a better Q point stability when _________ . (a) Re is small (b) b is small but Re is large (c) both b and Re are large
Q.3
(c) resistor
(b) Collector to base
(c) Voltage divider
(Ans. : c)
Which of the following is assumed in the approximate analysis of a voltage divider circuit ? (a) IB is essentially zero amperes. (b) R1 and R2 are considered to be series elements. (c) bRE ³ 10 R2
Q.6
(d) All of the above.
(Ans. : d)
For what value of b does the transistor enter the saturation region ? VCC = + 12 V
RC 2 kW
RB
200 kW
A.C. input
C1
C2
A.C. output
10 mF b = 50
10 mF
(a) 20
(b) 50
(c) 75
(d) 116
(Ans. : d)
qqq
TM
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3 - 16
Notes
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BJT Biasing
4
Introduction to Operational Amplifiers Chapter at a Glance
1.
Op-amp Symbol and Terminals
Inverting input terminal 2 3 Non-inverting input terminal
Positive supply voltage +VCC – 7 Op-amps
6
Output terminal
+
4 –VEE Negative supply voltage
Fig. 4.1 Op-amp symbol
2.
Differential Gain A d \
Vo = A d Vd Ad =
Vo Vd
A d = 20 Log 10 (A d ) in dB 3.
Common Mode Gain A c \
Vc =
V1 + V2 2
\
Vo = A c Vc
\
Vo = A d Vd + A c Vc
… Total output
(4 - 1) TM
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4.
5.
4-2
Introduction to Operational Amplifiers
Common Mode Rejection Ratio (CMRR) Ad Ac
\
CMRR = r =
\
CMRR in dB = 20 log
Ad Ac
dB
Ideal Op-amp Characteristics Characteristics
Symbol
Values
Open loop voltage gain
AO L
¥
Input impedance
R in
¥
Output impedance
Ro
0
Offset voltage
V oo
0
Bandwidth
B.W.
¥
C.M.R.R
r
¥
Slew rate
S
¥
Power supply rejection ratio
PSRR
0
Table 4.1 Ideal op-amp characteristics
6.
Voltage Levels and Saturating Property of Op-amp
Practically the op-amp output saturates at the voltages slightly less than the supply voltages + VCC and - V EE . 7.
Closed Loop Configuration of Op-amp This introduces negative feedback Rf V2 V1
Feedback resistor
– Op-amp
Vo
+
Overall finite gain
Fig. 4.2 Op-amp with negative feedback TM
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8.
4-3
Characteristics of Practical Op-amp | I b1 | + | I b2 | 2
Input bias current,
Ib =
Input offset current,
Iios = | Ib1 – Ib2|
9.
Introduction to Operational Amplifiers
Op-amp IC 741 Sr. No.
Parameter
Symbol
Ideal
Typical for 741 IC
1.
Open loop voltage gain
AOL
¥
2 ´ 105
2.
Output Impedance
Z out
0
75 W
3.
Input Impedance
Z in
¥
2 MW
4.
Input offset current
Iios
0
20 nA
5.
Input offset voltage
Vios
0
2 mV
6.
Bandwidth
B.W
¥
1 MHz
7.
CMRR
r
¥
90 dB
8.
Slew rate
S
¥
0.5 V/ msec
9.
Input bias current
Ib
0
80 nA
10.
Power Supply Rejection Ratio
PSRR
0
30 mV/V
Table 4.2
10. Realistic Simplifying Assumptions
· The steps of analysis based on these assumptions are, Step 1 : Input current of the ideal op-amp is always zero. Using this, the current distribution in the circuit is obtained. Step 2 : The input terminals of the op-amp are always at the same potential. Thus if one is grounded, the other can be treated to be virtually grounded. From this, the expressions for various branch currents can be obtained. Step 3 : Analyzing the various expressions obtained, eliminating unwanted variables, the output expression in terms of input and circuit parameters can be obtained.
TM
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4-4
Introduction to Operational Amplifiers
11. Ideal Inverting Amplifier +
Rf
–
I R1
+
+
Vin –
I
–
–
A Ib = 0 Op-amp + B
I
+ Vo –
Fig. 4.3 Inverting amplifier
AV =
\
R Vo = – f (Gain with feedback) R1 Vin
12. Ideal Non-Inverting Amplifier R1 –
I
Rf
A +
I
–
+ I
– + Vin –
Op-amp
+
B
Vo + –
Fig. 4.4 Non-inverting amplifier
AV =
R Vo =1+ f R1 Vin
Important Point Regarding Non-inverting Amplifier :
· In non-inverting amplifier the input may not be applied directly to the non-inverting terminal as considered while deriving the output expression but it may be applied through some circuit. · Let Vin is the input voltage applied to the non-inverting amplifier through some resistive network such that the voltage available at the non-inverting input terminal is VB which is different than Vin . Then the non-inverting amplifier always amplifies voltage available to its non-inverting terminal by the factor R R ö æ (1 + f ). Hence V o = ç 1 + f ÷V B . R1 R1 ø è TM
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4-5
Introduction to Operational Amplifiers
13. Voltage Follower – A
Vin
Vo
+
B
+ –
Fig. 4.5 Voltage follower
Vo = Vin 14. Inverting Summing Amplifier
V1
V2
Rf
R1
+
I
I1
–
– A
R2
+
I2
–
Vo
+
B
Fig. 4.6 Inverting summer
\
R ù éR Vo = – ê f V1 + f V2 ú R R û ë 1 2
If the two resistances are equal, R 1 = R 2 = R, Vo = -
Rf ( V1 + V2 ) R
15. Non-inverting Summing Amplifier Rf R
– A
I V1 V2
R1
R2
I
I1
+
B
Vo
I2
Fig. 4.7 Non-inverting summing amplifier TM
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4-6
Vo =
i.e.
Introduction to Operational Amplifiers
R 2 (R + R f ) R (R + R f ) V1 + 1 V R (R1 + R 2 ) R (R1 + R 2 ) 2
If the two resistances R 1 and R 2 are selected equal i.e. R 1 = R 2 then, Vo =
R + Rf ( V1 + V2 ) 2R
16. Average Circuit R1 = R 2 = R 3 = … = R n = R
and
R n
Rf =
17. Difference Amplifier or Subtractor Rf
V1
V2
I1
R1
+
I1 R2
+
–
A
Vo
+
B
I2 Rf
I2
Fig. 4.8 Subtractor circuit
Vo = –
\
Rf ù é R ù é Rf V V + 1+ f R1 1 êë R1 úû êë R 2 + R f úû 2
18. Integrator I R1 Vin
I
–
A
Cf Vo
+
B
Fig. 4.9 Op-amp integrator
Vo = –
1 R1 Cf
t
ò
0
Vin dt + Vo (0)
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4-7
Introduction to Operational Amplifiers
19. Differentiator Rf I1
C1
Vin
–
A
I1
B
+
Vo
Fig. 4.10 Op-amp differentiator
Vo = – C1 R f
d Vin dt
Important Theory Questions and Answers
Ø
List the various ideal op-amp characteristics. + VTU : Aug.-99, 2000, 01, 03, Feb.-03, 04, 05, July-08,09, Jan.-07, 08,10,11,13,14, June-12, Marks 6
a) Infinite voltage gain : (A OL = ¥) b) Infinite input impedance : (R in = ¥) c) Zero output impedance : (R o = 0) d) Zero offset voltage : (Vios = 0) e) Infinite bandwidth f) Infinite CMRR : ( r = ¥) g) Infinite slew rate : (S = ¥) h) No effect of temperature i) Power Supply Rejection Ratio : (PSRR = 0)
Ø
Draw an inverting amplifier using an op-amp and derive expression for its output voltage. + VTU : Aug.-2000, Mar.-2000, Marks 5 ; Feb.-03, Aug.-03, Marks 4; Jan.-10, 11, Marks 6
· Refer basic circuit diagram of an inverting amplifier using op-amp on page 4-4. · As node B is grounded, node A is also at ground potential, from the concept of virtual ground, so VA = 0 V – VA V = in (as VA = 0) … (4.1) I = in \ R1 R1 TM
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4-8
Introduction to Operational Amplifiers
· The op-amp input current is always zero hence entire current I passes through the resistance R f . · From the output side, considering the direction of current I we can write, V – Vo – Vo = (as VA = 0) I = A Rf Rf Vin R V = – o \ Vo = -Vin f · Equating (4.1) and (4.2) we get, R1 Rf R1
Ø
… (4.2)
Draw non-inverting amplifier using op-amp and derive expression for its output voltage. + VTU : Mar.-99, 2000, Aug.-2000, 02, 04, Feb.-03, 05, Marks 5; Aug.-06, Marks 8
· Refer basic circuit diagram of a noninverting amplifier using op-amp on page 4-4. · The node B is at potential Vin , hence the potential of point A is same as B which is Vin , from the concept of virtual ground. \ VA = VB = Vin I=
Vo – VA Rf
=
Vo – Vin Rf
( As VA = Vin )
… (4.1)
· At the inverting terminal, V –0 V = in ( As VA = Vin ) I = A R1 R1 · Equating equations (4.1) and (4.2),
Ø
Vo – Vin V = in Rf R1
… (4.2) R ö æ \ Vo = Vin ç 1 + f ÷ R1 ø è
Draw the circuit of voltage follower and obtain expression for its output voltage. Where it is + VTU : Aug.-99, 02, 03, Mar.-01, Feb.-06, July-11, Marks 6 used ?
· Refer voltage follower circuit using op-amp on page 4-5. · The node B is at potential Vin . · The node A is also at the same potential as B i.e. Vin according to the concept of virtual ground. \
VA = VB = Vin
… (4.1)
· Now node A is directly connected to the output. Hence we can write, Vo = VA Equating the equations (4.1) and (4.2), Vo = Vin
TM
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… (4.2)
Basic Electronics
Ø
4-9
Introduction to Operational Amplifiers
Draw the circuit of an integrator and derive the expression for its output voltage. VTU : Mar.-01,05, Jan.-08, 11, 13,July-09,11, Aug.-03, Feb.-03,04, June-13, Marks 5
+
· Refer the op-amp integrator circuit on page 4-6. · The node B is grounded. The node A is also at the ground potential. VA = VB = 0 V.
· From input side we can write, V – VA V = in (VA = 0 V) I = in R1 R1 · From output side we can write, d (VA – Vo ) dVo = – Cf I = Cf dt dt
… (4.1)
(VA = 0 V)
… (4.2)
· Equating the two equations (4.1) and (4.2) Vin dVo = – Cf R1 dt · Integrating both sides, we get, Vo = –
Ø
1 R1 Cf
t
ò
0
Vin dt + Vo (0)
Draw the circuit of differentiator and derive the expression for its ouput voltage. + VTU : Aug.-02, Feb.-03, 04, Jan.-11, 14, July-11, Dec.-11, Marks 5
· Refer op-amp differentiator circuit on page 4-7. · The node B is grounded. · The node A is also at the ground potential, hence VA = 0. · From the input side we can write, d (Vin – VA ) d Vin = C1 (VA = 0) I 1 = C1 dt dt (V – Vo ) V · From the output side we can write, I = A =– o Rf Rf d Vin Vo Equating the two equations, =– C1 dt Rf Vo = – C1 R f
d Vin dt
TM
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… (4.1) … (4.2)
Basic Electronics
4 - 10
Introduction to Operational Amplifiers
Important Solved Examples Example 4.1
An inverting amplifier circuit has input series resistor of 20 kW, feedback resistor of
100 kW and a load resistor of 50 kW. Draw the circuit and calculate the input current, load current, and the output voltage when the applied input voltage is equal to + 1.5 V.
+
VTU : Aug.-07, Marks 8
Solution : R1 = 20 kW, Rf = 100 kW, RL = 50 kW, Vin = 1.5 V The circuit is shown in the Fig. 4.11. Rf
Vin
R1
100 kW
I1
20 kW
– B A
I1 Vo
+ IL
RL = 50 kW
Fig. 4.11
The node A is grounded hence node B is at virtual ground. \ \
V A = VB = 0 V I1 =
Vin - VB 1.5 - 0 = = 75 mA R1 20 ´ 10 3
... Input current
The op-amp input current is zero hence same current I1 passes through the resistance Rf. VB - Vo 0 - Vo i.e. 75 ´ 10 -6 = I1 = \ Rf 100 ´ 10 3 \ \
Vo = -75 ´ 10 -6 ´ 100 ´ 10 3 = -7.5 V IL =
Vo -7.5 = = - 0.15 mA R 50 ´ 10 3 L
... Output voltage ... Load current
The negative sign indicates that IL flows from ground to output terminal i.e. upwards as Vo is negative.
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Example 4.2
4 - 11
Introduction to Operational Amplifiers
Find Vo for the circuit shown in the Fig. 4.12 50 k W
10 k W 1 kW
Vin 10 V
A
–
B
+
Vo
1 kW
Fig. 4.12
Solution : This is non-inverting amplifier but it will amplify VB by 1 +
Rf and not R1
Vin =10 V. The op-amp input current is zero hence part of the circuit is as shown in the Fig. 4.12 (a). \
I =
1 ´ 10 3 + 1 ´ 10 3
and
VB = I ´
\
VB =
\
Vo =
Vin 2 ´ 10 3
Iin = 0 A 1 kW
( 1 ´ 10 3 )
I
´ 1 ´ 10 3 =
Fig. 4.12 (a)
Vin 10 =5V = 2 2
R ö æ ç 1 + f ÷ VB R1 ø è
æ 50 ´ 10 3 = ç1 + ç 10 ´ 10 3 è Example 4.3
VB
1 kW
Vin
Vin
ö ÷ 5 = 30 V ÷ ø
A non inverting amplifier has input resistance 10 kW and feedback resistance
60 kW with load resistance 47 kW. Draw the circuit and calculate output voltage, voltage gain and load current when input voltage is 1.5 V. Solution : R1 = 10 kW ,
Rf = 60 kW,
RL = 47 kW,
+
VTU : Feb.-08, Marks 8
Vin = 1.5 V
The circuit is shown in the Fig. 4.13. The node A is at Vin hence due to the concept of virtual ground, the node B is also at Vin. VB = VA = Vin = 1.5 V \ \
I1 =
VB - 0 1.5 = = 0.15 mA R1 10 ´ 10 3
As op-amp current is zero, the same current flows through Rf. TM
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4 - 12
Introduction to Operational Amplifiers
Rf I1
R1
– B
10 kW
Vo
+
A Vin 1.5 V
60 kW I1
RL
+ _
47 kW
IL
Fig. 4.13
\
I1 =
Vo – VB Rf
i. e.
Vo – 1.5 60 ´ 10 3
= 0.15 ´ 10 -3
Vo = 0.15 ´ 10 -3 ´ 60 ´ 10 3 + 1.5 = 10.5 V
\
Voltage gain =
Vo 10.5 = = 7 Vin 1.5
Cross check that voltage gain = 1 + \
IL =
Vo R
L
Example 4.4
=
10.5 47 ´ 10 3
Rf 60 = 1+ =7 R1 10
= 0.2234 mA
... Load current
Design a scaling adder circuit using an OP-AMP to give the output -
Vo = - ( 3 V1 + 4V2 + 5 V 3 ), given the inputs V1 , V2 , V 3. . Solution : The circuit of inverting scaling adder is shown in the Fig. 4.14. The output of this circuit is given by,
+
VTU : Aug.-05, 08, Marks 8 Rf
R1
V1
R2
V2
–
R3
V3
+VCC Vo
+ –VEE
R R éR ù Vo = - ê f V1 + f V2 + f V 3 ú R R R 2 3 ë 1 û The required output is, Vo = - [3 V1 + 4 V2 + 5 V 3 ] Rf = 3, \ R1 Rf Rf = 4, =5 R2 R3 Choose
... Output voltage
Fig. 4.14
Rf = 100 kW TM
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Introduction to Operational Amplifiers
R1 = 33.33 kW, R2 = 25 kW, R3 = 20 kW \ The supply voltages may be selected as ± 15 V with IC 741 op-amp. Find the output voltage for the circuit below.
Example 4.5
+
VTU : Aug.-09, Marks 6
1 kW 1 kW
– 10 V
200 W
–
+5V + 20 V
Vo
+
400 W
Fig. 4.15
Solution : The circuit is inverting summing amplifier with,
\
R1 = 1 kW ,
R2 = 200 W,
V1 = – 10 V,
V2 = 5 V,
R3 = 400 W,
Rf = 1 kW
V3 = 20 V
R R éR ù Vo = – ê f V1 + f V2 + f V 3 ú R R R 2 3 ë 1 û 1000 1000 é 1000 ù =–ê ´ ( -10) + ´ 5+ ´ 20ú = - 65 V 3 200 400 ë1 ´ 10 û
But op-amp can not produce output greater than the saturation voltages according to its saturation property. \
Vo = ± Vsat
Multiple Choice Questions with Answers Op-amp Symbol and Terminals Q.1
An inverting input indicates _________ phase shift between input and output. (a) 0º
Q.2
(b) 180º
(d) 90º.
(Ans. : b)
The noninverting input indicates the phase shift of _____ between output and input of op-amp. (a) 0º
Q.3
(c) 360º
(b) 180º
(c) 90º
(d) 270º
(Ans. : a)
The supply voltage range of an op-amp is ________. (a) ± 5 to ± 22 V
(b) ± 7 to ± 12 V
(c) ± 12 V to ± 25 V
(d) none of these. TM
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(Ans. : a)
Basic Electronics
Q.4
4 - 14
Introduction to Operational Amplifiers
The output of an op-amp is measured with respect to ______ . (a) negative supply
(b) noninverting point
(c) positive supply
(d) ground.
(Ans. : d)
Ideal Op-amp Q.1
The differential gain is expressed in dB as ______ . (a) 10 log A
Q.2
(b) 20 log
1 A
(c) 20 log A
(d) 10 log
1 . A (Ans. : c)
An op-amp has open loop gain of 105 and two inputs are 500 mV and 700 mV at inverting and noninverting terminals respectively. Its output voltage is _______ . (a) 10 V
Q.3
Q.4
(c) 25 V
(d) 20 V.
(Ans. : d)
The gain with which differential amplifier amplifies the common signal is called ________ . (a) common mode gain
(b) differential gain
(c) constant gain
(d) none of these
(Ans. : a)
The ideal value of common mode gain is _______. (a) infinite
Q.5
(b) 30 V
(b) zero
(c) very small
+
The CMRR is given by _______. (a) Ad × Ac
(d) none of these. (Ans. : b)
A (c) d Ac
A (b) c Ad
VTU : June-13
(d) 20 log
Ac . Ad (Ans. : c)
Q.6
The ability of the op-amp to reject common mode signal is called _______. (a) PSRR
Q.7
(b) open loop gain (c) closed loop gain
(d) CMRR.
(Ans. : d)
If the input is applied between the two inputs it is called _______ input. (a) common mode
(b) subtractor
(c) differential
(d) essential (Ans. : c)
Q.8
Op-amp is basically a ______ amplifier. (a) power
Q.9
Q.10
(b) differential
(c) optical
(d) current (Ans. : b)
In the common mode operation the signals applied to the two inputs are ______. (a) of same magnitude and same sign
(b) of same magnitude and opposite sign
(c) of different magnitudes but different sign
(d) of different magnitudes and same sign. (Ans. : a)
The common mode input signal will produce Vo = ______. (a) + VCC
(b) 0
(c) -VCC
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(d) infinite
(Ans. : b)
Basic Electronics
Q.11
4 - 15
The differential gain of a differential amplifier is defined as ______. (b) Vd Vo
(a) Vo Vd
Q.12
(b) Vd Vo (b) 0 (b) only Vd
(c) Vo Vc
(d) Vo Vin
(c) infinite
(d) 12 ´ 105 (Ans. : c)
(Ans. : c)
(c) Vc and Vd
(d) none of these (Ans. : b)
(c) 0
(d) ¥
The ideal value of CMRR is ______. (b) 2 ´ 105
(a) 90 dB
Q.16
(Ans. : a)
Output voltage of a differential amplifier is ideally decided by ______. (a) only Vc
Q.15
(d) Vo Vin
The ideal value of differential gain is ______. (a) 2 ´ 105
Q.14
(c) Vo Vc
The common mode gain of a differential amplifier is defined as ______. (a) Vo Vd
Q.13
Introduction to Operational Amplifiers
(Ans. : d)
The differential amplifier amplifies _______ . (a) the voltage only at inverting terminal. (b) the voltage only at noninverting terminal. (c) the difference between the two input voltages. (d) none of these.
Q.17
(Ans. : c)
The gain with which differential amplifier amplifies the difference between input signals is denoted as _______ . (b) Ad
(a) A c
Q.18
Q.20
(b) mV/V
Q.23
(d) V / ms
(Ans. : a)
(Ans. : b)
The op-amp is basically a ---------- amplifier. (b) differential (d) common-signal
(Ans. : b)
CMRR should be (a) unity (c) much larger than unity
Q.22
(c) mV V
An op-amp having Ac = 1 dB and Ad = 100 dB has CMRR = _______ . (a) 100 dB (b) 99 dB (c) 10 dB (d) 1 dB (a) positive feedback (c) common emitter
Q.21
(d) none of these. (Ans. : b)
The units of CMRR are ______. (a) dB
Q.19
(c) A F
b) zero d) much smaller than unity
+
(Ans. : c)
VTU : Jan.-11
The differential amplifier has (a) one input and one output
b) two inputs and two outputs
(c) two inputs and one output
d) one input and two outputs
An op-amp has _________ o/p impedance. TM
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+ +
(Ans. : b)
VTU : July-11 VTU : June-12
Basic Electronics
Q.24
Q.25
4 - 16
Introduction to Operational Amplifiers
A) ¥
B) 0
C) 10000 W
D) 600 W
(Ans. : b)
Ideally open loop gain of op-amp is _________ (a) 0
b) y
(c) ¥
d) negative
+ 108 .
For a differential amplifier Ad = 10000 and CMRR = A) 10
-4
B) 10
(Ans. : c)
-6
VTU : Jan-14
What is the value of A c?
4
C) 10
D) 100
+
(Ans. : a)
VTU : Dec.-11
Ideal Op-amp Characteristics Q.1
The slew rate of the op-amp is ________ . (a) the maximum rate of change of output voltage. (b) the maximum rate of change of input voltage. (c) the maximum rate of change of feedback voltage. (d) none of these.
Q.2
(Ans. : a)
Ideal value of open loop gain of op-amp is ______ . (a) unity
Q.3
(b) zero (b) zero
Q.6
Q.7
Q.8
(c) 100
(d) infinite. (Ans. : b)
The input resistance of an ideal op-amp is _______.. (a) unity
Q.5
(d) infinite. (Ans. : d)
The input current of an ideal op-amp is ______ . (a) unity
Q.4
(c) 100
(b) zero
(c) 1000
(d) infinite. (Ans. : d)
For the ideal op-amp, the two input bias currents are ________. (a) equal and opposite
(b) zero
(c) of different magnitudes
(d) infinite.
(Ans. : b)
The ideal op-amp does not load any source due to its _________. (a) high CMRR
(b) high open loop gain
(c) high slew rate
(d) high input resistance
(Ans. : d)
An ideal op-amp can drive infinite number of circuits without difficulty because______. (a) low output resistance
(b) low input bias currents
(c) low common mode gain
(d) CMRR = ¥
(Ans. : a)
The bandwidth means frequency range over which _____ remains constant. (a) resistance
(b) CMRR
(c) gain
(d) slew rate (Ans. : c)
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Q.9
4 - 17
An ideal op-amp has _______ gain, _______. input impedance and _____ output impedance. (a) 0, 0, ¥
Q.10
(b) ¥ , 0, ¥
D Vo DV
(b)
Q.15
Q.18
Q.19
(c) mV V (c) mV V
(b) 1
(c) ¥
(a) input bias current
(b) slew rate
(c) bandwidth
(d) input offset voltage
(Ans. : d)
(d) no units (Ans. : c) (d) V / ms
(Ans. : d)
(d) 100
(Ans. : b)
(Ans. : b)
The effect of change in supply voltage on op-amp performance is judged by _______. (b) PSRR
(c) slew rate
(d) none of these (Ans. : b)
The maximum rate at which ampliifer output can change in volts per microsecond (V / ms ) is called ________ (b) slew rate
(c) under rate
(d) none
(Ans. : b)
The op-amp can amplify (a) AC signal only
(b) DC signal only
(c) Both AC and DC signals
(d) None of these
+
(Ans. : c)
VTU : Jan.-11
An ideal OP-AMP has (a) infinite input impedance
(b) infinite voltage gain
(c) zero output resistance
(d) all of these
The ideal bandwidth of an op-amp is __________ . b) infinity
c) high 5
b) 2 ´ 10
c) 0
The PSRR is generally measured in _______. a) dB
+ +
b) mV/ V
c) mV/ V
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(Ans. : d)
VTU : July-11 VTU : Dec.-11
d) medium (Ans. : b)
+
The ideal value of CMRR is _______. a) 90 dB
Q.21
D Vios DV
(d)
The highest frequency for which op-amp produces undistorted output depends on ______.
a) zero
Q.20
DV D Vios
The slew rate is generally specified at ______ gain.
(a) over rate
Q.17
(c)
(b) mV/V
(a) CMRR
Q.16
(Ans. : d)
The slew rate is generally measured in ______.
(a) 10
Q.14
D Vin DV
(b) mV/V
(a) dB
Q.13
(d) ¥ , ¥ ,0
The PSRR is generally measured in ______. (a) dB
Q.12
(c) ¥ , ¥ , ¥
The power supply rejection ratio (PSRR) is defined as ______. (a)
Q.11
Introduction to Operational Amplifiers
VTU : Jan.-13
d) ¥
+
(Ans. : d)
VTU : Jan.-13
d) V/ mS
(Ans. : c)
Basic Electronics
4 - 18
Introduction to Operational Amplifiers
Voltage Levels and Saturating Property of Op-amp Q.1
The output of op-amp can swing between ______due to its saturable property. (b) + VCC to -VEE
(a) 0 to + VCC
Q.2
(c) 0 to ¥
(d) none of these (Ans. : b)
Practically the maximum output voltage of op-amp is ______ supply voltage . (a) more than
(b) same as
(c) less than
(d) none of these. (Ans. : b)
Closed Loop Configuration of Op-amp Q.1
In most of the applications the op-amp is used in the ______ mode. (a) open loop
Q.2
Q.3
(a) inverting amplifier
(b) voltage follower
(c) integrator
(d) comparator.
(d) none of these. (Ans. : b)
(Ans. : d)
When input and feedback signal are in phase, the feedback is called _______ feedback. (b) zero
(c) infinite
(d) positive (Ans. : d)
When input and feedback signal are out of phase, then the feedback is called _______ feedback. (a) negative
Q.5
(c) saturated
The op-amp is used in the open loop mode for the ______ application.
(a) negative
Q.4
(b) closed loop
(b) zero
(c) infinite
(d) positive (Ans. : a)
Due to the negative feedback, the gain _______. (a) increases
(b) reduces
(c) remains same
(d) none of these (Ans. : b)
Characteristics of Practical Op-amp Q.1
To increase the input resistance of op-amp ______ is used . (a) BJT
Q.2
(b) FET
(c) transformer
(d) diodes
(c) I b1 - I b2
(d) I b1 + I b2
(Ans. : b)
The input bias current is given by ________. (a)
I b1 + I b2 2
(b)
I b1 - I b2 2
(Ans. : a)
Q.3
The input offset current is given by ________. (a)
I b1 + I b2 2
(b)
I b1 - I b2 2
(c) I b1 - I b2
(d) I b1 + I b2 (Ans. : c)
Q.4
Ideal value of the input bias current is ______. (a) 20 nA
(b) 10 mA
(c) 10 nA TM
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(d) 0
(Ans. : d)
Basic Electronics
Q.5
4 - 19
The characteristics input offset voltage and input bias current of op-amp, depend on ______. (b) temperature
(a) RL
Q.6
Q.8
(c) -VCC
(d) + VCC
(Ans. : b)
The input bias current is ______ the input offset current. (a) less than
Q.7
Introduction to Operational Amplifiers
(b) greater than
(c) same as
(d) none of these (Ans. : b)
When both the inputs of op-amp are grounded, the voltage across the output is called --------------------------. (a) output offset voltage
(b) output grounded voltage
(c) output bias voltage
(d) output common voltage.
(Ans. : a)
The voltage gain of an OP-amp in the open loop condition is of the order of (a) 10 (c) 10
1
b) 10
4
d) 10
2 6
+
(Ans. : d)
VTU : July-11
Block Diagram of Op-amp Q.1
Q.2
The function of level shifter stage is _______ . (a) to produce exact sinusoidal signals.
(b) to bring d.c. level down to zero.
(c) to suppress common mode signals.
(d) all of the above.
(Ans. : b)
______ is used as an input stage of IC op-amp. (a) Single input single output differential amplifier (b) Single input dual output differential amplifier (c) Dual input dual output differential amplifier (d) Dual input single output differential amplifier.
Q.3
Q.4
Q.5
(Ans. : c)
______ is used as an output stage of IC op-amp. (a) CB amplifier
(b) Class C amplifier
(c) Push pull amplifier with class B
(d) None of these.
(Ans. : c)
_______ are used as an intermediate stage in IC op-amp. (a) Feedback amplifier
(b) Multistage amplifier
(c) Single stage amplifier
(d) None of these
(Ans. : b)
The PSRR is the ratio of change in ________ to the change in the supply voltage producing it. (a) input offset current
(b) input offset voltage
(c) input bias current
(d) differential input voltage.
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(Ans. : b)
Basic Electronics
Q.6
4 - 20
Introduction to Operational Amplifiers
Buffer and level shifter is usually a ________ . a) current follower
b) collector follower
c) resistance follower
d) emitter follower
+
VTU : Dec.-11 (Ans. : d)
Op-amp IC 741 Q.1
The IC 741 uses a ______ polarity supply. (a) single
Q.2
(b) 1000
(c) 0
(d) infinite
(Ans. : a)
(b) 2 ´ 106
(c) 0
(d) infinite
(Ans. : b)
(b) 2 ´ 106
(c) 2 ´ 10-9
(d) 20 ´ 10-9 (Ans. : d)
(b) 2 ´ 10-6
(c) 2 ´ 10-9
(d) 0
(Ans. : a)
(b) 1´ 106
(d) infinite
(Ans. : b)
(c) 100 ´ 106
(d) infinite
(Ans. : b)
(c) infinite
(d) 112 dB (Ans. : a)
(c) 100 ´ 106
The value of slew rate of IC 741 is ______V/sec. (a) 10 ´ 106
Q.9
(Ans. : b)
The value of bandwidth of IC 741 is ______Hz. (a) 10 ´ 106
Q.8
(d) 2 ´ 109
The value of input offset voltage of IC 741 is ______volts. (a) 2 ´ 10-3
Q.7
(c) 0
The value of input offset current of IC 741 is ______amperes. (a) 0
Q.6
(b) 2 ´ 105
The value of input impedance of IC 741 is ______ohms. (a) 7500
Q.5
(d) unbalanced (Ans. : b)
The value of output impedance of IC 741 is ______ohms. (a) 75
Q.4
(c) negative
The value of open loop voltage gain of IC 741 is ______ . (a) ¥
Q.3
(b) dual
(b) 0.5 ´ 106
The value of CMRR of IC 741 is ______. (a) 90 dB
(b) 0 dB
Realistic Simplifying Assumptions Q.1
Which of the following statement is true for the concept of virtual ground ? (a) Both input terminals carry equal current. (b) Both input terminals are directly grounded. (c) Both input terminals are at same potential. (d) None of these.
Q.2
(Ans. : c)
According to ______ concept, the two input terminals are at same potential for the op-amp. (a) virtual short
(b) positive feedback
(c) infinite Ro
(d) none of these
(Ans. : a) TM
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Basic Electronics
4 - 21
Introduction to Operational Amplifiers
Ideal Inverting Amplifier Q.1
The phase shift between input and output in an inverting amplifier is _____ . (a) 0º
Q.2
Q.5
(d) 270º.
+
(Ans. : b)
(b) –11
(c) 10
VTU : June-13
(d) 11.
(Ans. : a)
In an inverting amplifier if gain is one then the circuit is called _______ . (a) Schmitt trigger
Q.4
(c) 90º
The gain of the inverting amplifier using Rf = 10 kW and R1 = 1 kW is _______ . (a) –10
Q.3
(b) 180º
(b) summer
(c) phase inverter
(d) rectifier (Ans. : c)
Which of the following circuit is used as a scale changer ? (a) Schmitt trigger
(b) inverting amplifier
(c) phase shifter
(d) noninverting integrator.
(Ans. : b)
Find the output voltage of the given circuit. 10 k W
2 kW
– Vo
+ 1V
(a) 5 V
Q.6
+ _
(b) 20 V
(c) 6 V
(d) – 5 V
(c) integrator
(d) subtractor (Ans. : a)
(Ans. : c)
The circuit shown represents _______. R
R
– +
(a) sign changer
Q.7
In an inverting amplifier, R1 = 1 K and Rf = 2 K. If input voltage is 2 V, output voltage is (a) - 2 V
Q.8
(b) differentiator
(b) - 0.5 V
(c) 4 V
(d) - 4 V.
(Ans. : d)
The inverting amplifier circuit has Ri = 1 kW and Rf = 3 kW. The output voltage is ____ when vi = 4V. TM
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Basic Electronics
4 - 22
(a) 6 V
Q.9
Q.10
b) 16V
Introduction to Operational Amplifiers
(c) 12V
d) 18V
+
(Ans. : c)
VTU : Jan.-11
In an inverting amplifier there is ____ phase shift between input and output. (a) 0º
b) 90º
(c) 180º
d) 360º
+
(Ans. : c)
VTU : Jan.-14
For an inverting op-amp if R1 = R F then circuit is called _______ . a) sign changer
b) sign multiplier
c) + ve sign
d) none of these (Ans. : a)
+
VTU : Dec.-11
Ideal Non-Inverting Amplifier Q.1
The phase shift between input and output in a noninverting amplifier is _____ . (a) 0º
(b) 180º
(c) 90º
(d) 270º.
(Ans. : a)
Q.2
The gain of the noninverting amplifier using Rf = 10 kW and R1 = 1 kW is _______ . (a) –10 (b) –11 (c) 10 (d) 11 (Ans. : d)
Q.3
The closed loop gain of ______ circuit is always greater than 1. (a) inverting amplifier (b) noninverting amplifier (c) voltage follower
(d) none of these
(Ans. : b)
Q.4
The input resistance of noninverting amplifier is ______ that of a inverting amplifier. (a) less than (b) greater than (c) equal to (d) none of these (Ans. : b)
Q.5
An inverting amplifier using Rf = 10 kW and R1 = 1 kW has a gain of _______. (a) – 0.1
Q.6
(b) + 0.1
(c) – 10
(d) + 10.
(Ans. : c)
The output voltage of the amplifier shown in the Fig. 4.16 is _______V. 5 kW
1 kW
– R
Vo
+
+2V R
Fig. 4.16 (a) + 2 V
(b) + 12 V
(c) + 6 V
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(d) – 6 V
(Ans. : c)
Basic Electronics
Q.7
4 - 23
Introduction to Operational Amplifiers
An op-amp non-inverting amplifier has R1 = 1kW and Rf = 3 kW when Vi = - 2 V, the output is _________. VTU : June-12 a) – 4 V b) 4 V c) 8 V d) – 8 V (Ans. : d)
+
Voltage Follower Q.1 Q.2
The gain of the voltage follower is _______ . (a) zero (b) infinite (c) negative
(d) none of these (Ans. : a)
(c) greater than 1
(d) less than 1 (Ans. : a)
For a noninverting amplifier Rf = 10 kW and R1 = 1 kW then its gain is 1 (c) 11
(b) –11
_______.
(d) + 11.
(Ans. : d)
The input resistance of voltage follower is _______ . (b) very low
(c) zero
(d) none of these. (Ans. : a)
The voltage follower is commonly used as _______. (b) isolator
(c) regulator
(d) none of these (Ans. : b)
An OP-AMP shorted between inverting terminal and output terminal is called (a) adder
Q.10
R ö æ (c) ç1 + f ÷ R1 ø è
(b) 0
(a) switch
Q.9
(Ans. : a)
The feedback factor b of the voltage follower circuit is ______.
(a) very high
Q.8
(d) none of these
(b) -Rf R1
(a) +1.1
Q.7
(Ans. : b)
The closed loop gain of a voltage follower is ______ .
(a) 1
Q.6
(Ans. : d)
The voltage follower is practically used to _______ . (a) reducing loading effect (b) increasing efficiency
(a) 1
Q.5
(d) unity.
(d) all the above.
(c) reducing offset error
Q.4
VTU : Jan.-13, June-13
The voltage follower has _______ property. (a) small bandwidth (b) large input resistance (c) large output resistance
Q.3
+
(b) voltage follower
(c) integrator
Op-amp configuration used as buffer is _________. (a) inverting amplifier (b) non inverting amplifier (c) voltages follower
(d) adder
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(d) inverter (Ans. : b)
+ +
VTU : July-11 VTU : June-12 (Ans. : c)
Basic Electronics
4 - 24
Introduction to Operational Amplifiers
Summing Amplifier or Adder Circuit Q.1
Find the output of the given circuit. 1 kW
1 kW 1V 2V
(a) 3 V
Q.2
1 kW
Vo
(b) – 3 V
(c) 2 V
(d) –2 V
(Ans. : b)
The circuit shown represents _______ . R
C
– +
(a) sign changer
Q.3
(b) differentiator
(c) integrator
(d) subtractor (Ans. : b) For getting average circuit from the inverting summer, R1 = R2 = R and ______. (b) Rf = 2R (c) Rf = R (d) none of these (a) Rf = R / 2 (Ans. : a)
Difference Amplifier or Subtractor Q.1
What is the output voltage of the following circuit ? R
R
–
1V 3V
R
+ R
TM
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Vo
Basic Electronics
4 - 25
(a) 2 V
Q.2
(b) –2 V
Introduction to Operational Amplifiers
(c) 4 V
(d) none of these. (Ans. : a)
(c) integrator
(d) subtractor (Ans. : d)
The circuit shown represents _______ . R
R
–
R
+ R
(a) sign changer
Q.3
(b) differentiator
__________ is the expression for output voltage of difference amplifier. (a) Vo = (c) Vo =
R1 (V - V2 ) Rf 1
(b) Vo =
Rf (V + V2 ) R1 1
Rf (V - V2 ) (d) none of these. R1 1
(Ans. : c)
Integrator Q.1
The circuit shown represents _______ .
R
C
– +
(a) sign changer
Q.2
(c) integrator
(d) subtractor (Ans. : c)
(c) Integrator
(d) None of these (Ans. : c)
_______ is used in analog computers. (a) Differentiator
Q.3
(b) differentiator
(b) Summer
If we apply a sine wave to an integrator, then we get ______ at its output. (a) cosine wave
(b) negative cosine wave
(c) sine wave
(d) triangular
(Ans. : a) TM
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Basic Electronics
Q.4
Q.5
4 - 26
If we apply a step waveform to an integrator, then we get ______ at its output. (a) cosine wave
(b) negative cosine wave
(c) ramp
(d) sine wave
Q.7
(b) passive
(b) resistor
(d) 0 Hz
(c) fH
dVin dt
(d) C1Rf
dVin dt
(Ans. : b)
(b) zero
(c) ramp
(d) cannot be decided (Ans. : c)
(c) bandpass
(d) low pass(Ans. : d)
An integrator acts as a ______ filter. (b) band reject
The time constant of an op-amp integrator is _______. R1 Cf
(b)
1 R1C f
(c)
Cf R1
(d) R1C f
(Ans. : d) When op-amp used as integrate with input as square wave the output will be ______. (a) Ramp (b) Triangular wave (c) Step
(d) Cosine wave
+
Differentiator Q.1
(Ans. : d)
For a pure d.c. input, the integrator output is ______.
(a)
Q.13
(d) inductor (Ans. : c)
The expression for output voltage of an inverting integrator is ______. 1 1 (b) (a) V dt + C V dt + C R1C f ò in R1C f ò in
(a) high pass
Q.12
(c) capacitor
(b) infinite
(a) triangular
Q.11
(d) composite (Ans. : a)
At the ___________ frequency, gain of an integrator is maximum.
(c) - C1Rf
Q.10
(d) composite (Ans. : b)
In an inverting ideal integrator a ______ is connected in the feedback path.
(a) 10 Hz
Q.9
(c) hybrid
The integrator using an op-amp is called ______ integrator. (a) active (b) passive (c) hybrid
(a) diode
Q.8
(Ans. : c)
The integrator not using an op-amp is called ______ integrator. (a) active
Q.6
Introduction to Operational Amplifiers
The circuit shown represents _______ . R
C
– +
TM
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(Ans. : b)
VTU : Jan-14
Basic Electronics
4 - 27
(a) sign changer
Q.2
(b) differentiator
Q.4
Q.5
(b) + w cos wt
(c) –100 w cos wt
(a) cosine wave
(b) negative cosine wave
(c) sine wave
(d) triangular
(d) none of these (Ans. : a)
(Ans. : b)
If we apply a square waveform to a differentiator, then we get ______ at its output.
+
(a) cosine wave
(b) negative cosine wave
(c) ramp
(d) train of impulses
VTU : Jan.-13 (Ans. : d)
In an inverting ideal differentiator a ______ is connected in the feedback path. (b) resistor
(c) capacitor
(d) inductor (Ans. : b)
The expression for output voltage of differentiatior is ______. (a)
1 R1C f
ò
(c) - C1Rf
Q.7
(d) subtractor (Ans. : b)
If we apply a sine wave to a differentiator, then we get ______ at its output.
(a) diode
Q.6
(c) integrator
If input to an differentiator using R = 100 kW and C = 0.1 mF is 100 sin wt then the output equation is _______ . (a) – w cos wt
Q.3
Introduction to Operational Amplifiers
(b) -
Vin dt + C dVin dt
1 R1C f
(d) C1Rf
ò
Vin dt + C
dVin dt
(Ans. : c)
A differentiator acts as a ______ filter. (a) high pass
(b) band reject
(c) bandpass
(d) low pass (Ans. : a)
qqq
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Basic Electronics
4 - 28
Introduction to Operational Amplifiers
Notes
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5
Digital Electronics
Chapter at a Glance Important Definitions 1. Digital/discrete signal : A digital/discrete signal is a signal that can have one of a finite set of possible values at any time. 2. Analog/continuous signal : An analog/continuous signal is a signal that can have one of an infinite number of possible values. 3. Binary signal : In digital systems, the most common digital signal is the signal that has one of two possible values, like on or off (often represented as 1 or 0). Such signal is known as binary signal. 4. If the higher of the two voltages represents a 1 and the lower voltage represents a 0, the system is called a positive logic system. 5. If the lower voltage represents a 1 and the higher voltage represents a 0, we have a negative logic system. 6. The 1’s complement : The 1’s complement of a binary number is the number that results when we change all 1’s to zeros and the zeros to ones. 7. The 2’s complement : The 2’s complement is the binary number that results when we add 1 to the 1’s complement. It is given as 2’s complement = 1’s complement + 1 8. Variable : The symbol which represent an arbitrary elements of an Boolean algebra is known as variable. (5 - 1) TM
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Digital Electronics
9. Constant : In expression Y = A + 1, the first term A is a variable and have value either a 1 or 0. The second term has a fixed value 1. So 1 is a constant here. The constant term may be 0 or 1. 10. Complement : A complement of a variable is represented by a "bar" over the letter. Sometimes a prime symbol (’) is used to denote the complement. 11. Literal : Each occurrence of a variable in Boolean function either in a complemented or an uncomplemented form is called a literal. 12. Boolean function : Boolean expressions are constructed by connecting the Boolean constants and variables with the Boolean operations. These Boolean expressions are also known as Boolean formulae. 13.
Postulates and basic theorems of Boolean algebra. Postulates
Postulate 1 Postulate 2 (Identity) Postulate 3 (Commutative) Postulate 4 (Distributive) Postulate 5 (Complement)
Theorems
(a)
(b)
Result of each operation is either 0 or 1 Î B A×1=A
A+0=A A+B =B+A
AB = BA
A (B + C) = AB + AC
A + BC = (A + B) (A + C) A×A=0
A+A =1
(a)
(b)
Theorem 1 (Idempotency)
A+A=A
A×A=A
Theorem 2
A+1=1
A×0=0
Theorem 3 (Involution)
A =A
Theorem 4 (Absorption)
A + AB = A
Theorem 5
A + AB = A + B
Theorem 6 (Associative)
A (A + B) = A A × (A + B) = AB
A + (B + C) = (A + B) + C
TM
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A (BC) = (AB) C
Basic Electronics
5-3
Digital Electronics
14. NOT gate (Inverter) : The output is a complement of input. Logic Diagram (Symbol) A
Switch Equivalent
Y
V
Pin Diagram
Truth Table
R
+ – S
1
VCC 14
2
13
3
12
Input
Output
Switch open (Low) Switch close (High)
Lamp ON (High) Lamp OFF (Low)
Input
Output
A
Y
0
1
1
0
Boolean Expression Y=A
IC 7404 4
11
VCC
5
10
R
6
9
7
GND
Application : Y
R
A
Used to complement (invert) digital signal.
8
Buffer : The output is same as input. Boolean Expression
Symbol
Truth Table
Y=A A
Y
Pin Diagram
Application : It is used to increase output driving capacity.
14
13
12
11
10
9
8
VCC
IC 7407
GND 1
2
3
TM
4
5
6
7
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Input
Output
A
Y
0
0
1
1
Basic Electronics
5-4
Digital Electronics
AND gate : The output is high only when all inputs are high. Logic Diagram (Symbol) A
Switch Equivalent
Input
Y
B
1
VCC 14
2
13
3
12
4
IC 7408
11
5
10
6
9
7
GND
Output
S2
S1
+ V
Pin Diagram
Truth Table
–
Input
Output S2
S1
Lamp OFF (Low)
Open (Low)
Open (Low)
Open (Low)
Close (High) Lamp OFF (Low)
Close (High) Open (Low)
A
B
Y
0
0
0
0
1
0
1
0
0
1
1
1
Lamp OFF (Low)
Close (High) Close (High) Lamp ON (High)
Diode Boolean Expression
Equivalent +VCC
8
R
Application :
A Y=A B
B
TM
Y = A×B
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Used to implement logical AND operation.
Basic Electronics
5-5
Digital Electronics
OR gate : The output is high when any of the inputs is high. Switch Equivalent
Logic Diagram (Symbol) A
Y
B
Pin Diagram
VCC 14
2
13
3
11
5
10
6
9
7
GND
B
Y
0
0
0
0
1
1
Output
1
0
1
Lamp OFF (Low)
1
1
1
Input
IC 7432
S2
Open (Low)
Open (Low)
Open (Low)
Close (High) Lamp ON (High)
Close (High) Open (Low)
Lamp ON (High)
Boolean Expression
Close (High) Close (High) Lamp ON (High)
Diode
8
Output
A
–
S1
12
4
Input
S2
+ V
1
Truth Table
S1
Y=A+B Application : Used to implement logical OR operation.
Equivalent A Y=A+B
B R
NAND gate : The output is high only when one of the inputs is low. Boolean Expression
Truth Table
Y = A×B
Symbol
Pin Diagram A B
14
Y
13
12
11
10
Input 9
8
VCC
IC 7400
Application : It can be used to implement any digital circuit.
GND 1
2
3
4
TM
5
6
7
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Output
A
B
Y
0
0
1
0
1
1
1
0
1
1
1
0
Basic Electronics
5-6
Digital Electronics
NOR Gate : The output is high when all the inputs are low. Boolean Expression Y=A+B Pin Diagram
Symbol
A B
14
Y
13
12
10
11
9
Truth Table Input 8
A
B
Y
0
0
1
0
1
0
1
0
0
1
1
0
VCC
IC 7402
Application : It can be used to implement any digital circuit.
GND 1
Exclusive OR (EX-OR) gate :
2
3
5
4
6
Output
7
The output is high only when odd number of inputs are high.
Symbol Truth Table
Boolean Expression A B
Y=AÅ B
Y
Application : It is used to implement magnitude comparator, gray code converter, adder/subtractor circuits, parity generator, modulo-2 adder, etc.
Input
Pin Diagram 14
13
12
11
10
9
8
VCC
IC 7486
GND 1
2
3
4
5
6
7
Output
A
B
Y
0
0
0
0
1
1
1
0
1
1
1
0
Exclusive NOR (EX-NOR) gate : The output is high only when even number of ones at the input or all inputs are high. Boolean Expression
Symbol
Truth Table
Y=AÅ B A B
Input
Pin Diagram
Y
14
Applications : It is used to implement even parity generator, comparator, even parity checker, etc.
13
12
11
10
9
8
VCC
IC 74266
Output
A
B
Y
0
0
1
0
1
0
1
0
0
1
1
1
GND 1
2
3
4
TM
5
6
7
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Basic Electronics
15. 16. 17.
5-7
Digital Electronics
The NAND and NOR gates are known as universal gates, since any logic function can be implemented using NAND or NOR gates. Half Adder : The logic circuit which adds two binary bits is called a half-adder. Full Adder : The circuit which performs addition of three bits (two significant bits and a previous carry) is a full-adder.
Important Questions and Answers
Ø
Differentiate analog and digital signals.
Sr. No.
Analog Signal
Digital Signal
1.
An analog signal is a signal that can have one of an infinite number of possible values.
A digital signal is a signal that can have one of a finite set of possible values at any time.
2.
Analog signal processing uses analog circuit elements, such as resistors, capacitors, inductors and active components such as operational amplifiers and non-linear devices.
Digital signal processing makes use of a special purpose computer, which has three basic elements, namely adders, multipliers, and memory for storage.
3.
Analog signal processing can be done in real time. It is more affected by noise.
There is no guarantee that the digital signal processing can be done in real time. It is less affected by noise.
4.
Analog signals consume less bandwidth than Digital signals consume more bandwidth digital signals to carry the same information. than analog signals to carry the same information.
5.
They are best suited for transmission of audio and video.
Ø Ø
They are best suited for transmission of computer data.
Draw a block diagram of half adder. Write truth table. Draw logic diagram. Write a truth table for half adder, reduce the equation using K-map and design half adder using logic gates.
The half-adder operation needs two binary inputs : augend and addend bits; and two binary outputs : sum and carry. The truth table shown in Table 5.1 gives the relation between input and output variables for half-adder operation. Inputs
Outputs
A
B
Carry
Sum
0
0
0
0
0
1
0
1
1
0
0
1
1
1
1
0
A Inputs B
Half adder
Carry Outputs Sum
Fig. 5.1 Block schematic of half-adder
Table 5.1 Truth table for half-adder
From the truth Table 5.1 we have Carry = AB and TM
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Digital Electronics
Sum = AB + AB = A Å B
Logic diagram A B
Limitations of Half-Adder :
Sum
In multidigit addition we have to add two bits alongwith the carry of previous digit addition. Effectively such addition Carry requires addition of three bits. This is not possible with Fig. 5.2 Logic diagram half-adder. Hence half-adders are not used in practice. for half-adder
Ø
Define full adder. Draw logic circuit and truth table of full adder.
A full-adder is a combinational circuit that forms the arithmetic sum of three input bits. It consists of three inputs and two outputs. Two of the input variables, denoted by A and B, represent the two significant bits to be added. The third input Cin, represents the carry from the previous lower significant position. The truth table for full-adder is shown in Table 5.2. Inputs
Cin
Outputs
A
B
Cin
Carry
Sum
0
0
0
0
0
0
0
1
0
1
0
1
0
0
1
0
1
1
1
0
1
0
0
0
1
1
0
1
1
0
1
1
0
1
0
1
1
1
1
1
A B
Full adder
Sum
Cout
Fig. 5.3 Block schematic of full-adder
Table 5.2 Truth table for full-adder
From Table 5.2 we have Carry = ABCin + ABCin + ABCin + ABCin QA + A = A
= ABCin + ABCin + ABCin + ABCin + ABCin + ABCin = BCin (A + A) + ACin (B + B) + AB (Cin + Cin) = BCin + ACin + AB Logic diagram A B Cin
A B A Cin
Cout
B Cin
A B Cin A B Cin
Sum
A B Cin
Fig. 5.4 Sum of product implementation of full-adder TM
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Basic Electronics
5-9
Digital Electronics
The Boolean function for sum can be further simplified as follows : Sum = A B Cin + A B Cin + A B Cin + A B Cin = Cin (A B + AB) + Cin (A B + A B) = Cin (A 8 B) + Cin (A Å B) = Cin (A Å B) + Cin (A Å B) = Cin Å ( A Å B) With this simplified Boolean function circuit for full-adder can be implemented as shown in the Fig. 5.5. A B Cin
Sum B A A
Cout
Cin Cin B
Fig. 5.5 Implementation of full-adder
Ø
Implement full adder using two half adders and one OR gate. Write the equations for sum and C out . + VTU : Jan. 14, Marks 6
A full-adder can also be implemented with two half-adders and one OR gate, as shown in the Fig. 5.6. The sum output from the second half-adder is the exclusive-OR of Cin and the output of the first half-adder, giving Cout = AB + A C in + B C in = AB + A C in (B + B) + B C in (A + A) = AB + ABC in + A B C in + ABC in + A BC in = AB (1 + C in + C in ) + A BC in + A BC in = AB + ABC in + ABC in = AB + C in (AB + AB) = AB + C in (A Å B) First half-adder
Second half-adder Cin Å (A Å B) Sum
A B
Cin (A Å B) Cin
AB
Cout
Fig. 5.6 Implementation of a full-adder with two half-adders and an OR gate TM
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5 - 10
Digital Electronics
Important Examples Example 5.1 Convert (125.62) 8 to binary.
Solution : Step 1 :
Write equivalent 3-bit binary number for each octal digit.
Step 2 :
Remove any leading or trailing zeros. 1
2
5
Step 1.
0 0 1 0 1 0 1 0 1
Step 2.
1 0 1 0 1 0 1
6
1 1 0 0 1 0 1 1 0 0 1
Leading zeros
\
Octal (Base 8)
2
Trailing zero
(125.62) 8 = (1010101.11001) 2
Example 5.2 Convert ( 8 A 9. B4 )16 to binary.
Solution : Step 1 :
Write equivalent 4-bit binary number of each hexadecimal digit.
Step 2 :
Remove any leading or trailing zeros. 8
A
9
B
4
Step 1.
1 0 0 0 1 0 1 0 1 0 0 1
1 0 1 1 0 1 0 0
Step 2.
1 0 0 0 1 0 1 0 1 0 0 1
1 0 1 1 0 1 Trailing zeros
\
(8A9. B4) 16 = (1000 1010 1001.101101) 2
Example 5.3 Convert (BC 66.AF)16 to its octal equivalent.
Solution : Step 1 : Step 2 : Step 3 :
Write equivalent 4-bit binary number for each hexadecimal digit. Make group of 3-bits starting from LSB for integer part and MSB for fractional part by adding 0s at the end, if required. Write equivalent octal number for each group of 3-bits. B
C
6
6
A
Step 1.
1 0 1 1 1 1 0 0 0 1 1 0 0 1 1 0
Step 2.
0 0 1 0 1 1 1 1 0 0 0 1 1 0 0 1 1 0
Step 3.
1
3
6
1
4
6
Adding 0s to make a group of 3-bits
Hex (Base 16)
F
1 0 1 0 1 1 1 1
Binary (Base 2)
1 0 1 0 1 1 1 1 0
Binary (Base 2)
5
3
6
Adding 0 to make a group of 3-bits TM
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Octal (Base 8)
Basic Electronics
5 - 11
Digital Electronics
Example 5.4 Convert 658.825 decimal into octal.
Solution : Integer part : Conversion of integer part by successive division method. Q
Q
R
658
¸
8
=
82
2
82
¸
8
=
10
10
¸
8
=
1
¸
8
=
LSD
R
8
658
2 LSD
2
8
82
2
1
2
8
10
2
0
1
8
1
1 MSD
MSD
1
2
2
0
2
(658)10 = (1222) 8
Fractional part : Conversion of fractional part by successive multiplication method. Fraction
Base
Product
0.825
×
8
=
6 . 6
0.6
×
8
=
4 . 8
0.8
×
8
=
6 . 4
MSD
6
4
6
LSD
\ (658.825)10 = (1222.646) 8
(0.825)10 = (0.646) 8
Example 5.5 Convert 5386.345 decimal into hexadecimal.
Solution : Integer part : Conversion of integer part by successive division method. Q
Q
R LSD
R
5386 ¸
16
=
336
10
336
¸
16
=
21
0
16
336
0
21
¸
16
=
1
5
16
21
5
1
¸
16
=
0
1
16
1
1
MSD
1
16 5386
5
0
A
(5386)10 = (150A) 16
TM
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0
10(A) LSD
MSD
Basic Electronics
5 - 12
Digital Electronics
Fractional part : Conversion of fractional part by successive multiplication method. Fraction
Base
Product
0.345
×
16
=
5 . 52
0.52
×
16
=
8 . 32
0.32
×
16
=
5 . 12
5
MSD
8
5
(0.345)10 = (0.585) 16
LSD
\ (5386.345)10 = (150A.585) 16
Example 5.6 Convert the following binary numbers to decimal numbers.
+ Solution : i)
(1101)2 =
VTU : Feb.-10, Marks 5
(1 ´ 2 3 ) + (1 ´ 2 2 ) + (0 ´ 2 1) + (1 ´ 2 0 )
= 8 + 4+ 1 = (13)10 ii)
(10001)2 =
(1 ´ 2 4 ) + (0 ´ 2 3 ) + (0 ´ 2 2 ) + (0 ´ 2 1) + (1 ´ 2 0 )
= 16 +1 = (17)10 iii)
(10101) =
(1 ´ 2 4 ) + (0 ´ 2 3 ) + (1 ´ 2 2 ) + (0 ´ 2 1) + (1 ´ 2 0 )
= 16 +4 +1 = (21)10 Example 5.7 Convert (725.25)8 to its decimal and binary equivalent.
+
Solution : (725.25)8 = ( = (
) 10 )2
(725.25)8 = 7 ´ 8 2 + 2 ´ 8 1 + 5 ´ 8 0 + 2 ´ 8 -1 + 5 ´ 8 -2 2 5 + 8 64 = 448 + 16 + 5 + 0.25 + 0.0781 = 7 ´ 64 + 2 ´ 8 + 5 ´ 1 +
= ( 469. 328) 10 (725.25) 8 = (111 010 101 . 010 101) 2
TM
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VTU : Feb.-07, Marks 5
Basic Electronics
5 - 13
Digital Electronics
+
Example 5.8 Convert ( 3576) 8 to hexadecimal.
Solution : ( 3576) 8 = (
) 16
or H
5
3
7
6
Octal
0 1 1 1 0 1 1 1 1 1 1 0 7
\
VTU : Feb.-07, Marks 5
7
Binary Hex
E
( 3576) 8 = (7 7 E)16
Example 5.9 Determine the value of base x, if i) (225)x = (341)8; ii) (211)x = (152)8
+
VTU : Jan.-14, Marks 6
+
VTU : July-11, Marks 8
Solution : i) (225)x = (341)8 Converting octal into decimal. (341)8 = 3 ´ 8 2 + 4 ´ 8 + 1 = (225)10 \
(225)x = (341)8 = (225)10
\
x = 10 i.e.
(225)10 = (341)8
ii) (211)x = (152)8 Converting octal into decimal (152)8 = 1 ´ 8 2 + 5 ´ 8 + 2 = (106)10 (211)x = 2 ´ x 2 + 1 ´ x + 1 ´ x 0 = (106)10
\ \
2x 2 + x + 1 = 106
\
x = 7
or x = – 7.5
x = – 7.5 is invalid \
x = 7
\
(211)7 = (152)8
Example 5.10 (101010111100)2 = (?)8 = (?)16
Solution :
1 0 1 0 1 0 1 1 1 1 0 0 5
7
2
4
Binary Number Octal Number
\ (101010111100)2 = (5274)8 = (ABC)16 1 0 1 0 1 0 1 1 1 1 0 0 A TM
B
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C
Binary Number Hex Number
Basic Electronics
5 - 14
Digital Electronics
+
Example 5.11 (240)10 (?)2 = (?)BCD
Solution : \
(240)10 = (11110000)2 (240)10 = (0010 0100 0000)BCD
VTU : July-11, Marks 8
2
240
0
2
120
0
2
60
0
2
30
0
2
15
1
2
7
1
2
3
1
2
1
1
LSD
MSD
0
Example 5.12 Add (28)10 and (15)10 by converting them into binary.
Solution : Using decimal to binary conversion technique we have,
+
Sign Extension Sign
(28) 10
Carry
1
1
1
0
0
1
1
1
0
0
Binary equivalent of (28)10
0
0
0
1
1
1
1
Binary equivalent of (15)10
0
1
0
1
0
1
1
Result : Binary equivalent of (43)10
(28)10 + (15) 10 (43)10
= (011100) 2 and (15) 10 = (01111) 2
Example 5.13 Perform (28)10 - (19)10 using 1's complement representation.
+
VTU : July-13, Marks 2
Solution : (28) 10 = (011100) 2 (19) 10 = (010011) 2 0
1
0
0
1
1
(19)10 Carry
1 + 1
1
0
1
1
0
0
1
1
1
0
1
1
1
0
0
Binary equivalent of (28)10
1
0
1
1
0
0
1's complement of 19, i.e. (–19)10
0
0
1
0
0
0
Result
1's complement of (19)10
Carry
+
(9)10
1 0
0
1
0
0
1
(28)10 + (–19)10
Final result : Binary equivalent of (9)10 TM
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Basic Electronics
5 - 15
Digital Electronics
Example 5.14 Perform (28)10 - (19)10 using 2's complement representation.
+
VTU : July-13, Marks 2
Solution : (28) 10 = (011100) 2 (19) 10 = (010011) 2 0
1
0
1
0
1
(19)10 Carry
1
0
1
1
0
0
1's complement of (19)10
1 1
0
1
1
0
1
Add 1 2's complement of 19, i.e., (–19)10
1
1
1
0
1
1
1
0
0
Binary equivalent of (28)10
1
0
1
1
0
1
2's complement of 19, i.e. (–19)10
0
0
1
0
0
1
Result : Binary equivalent of (09)10
+
1 + Ignore Carry
1
Carry
(28)10 + (–19)10 (09)10
Example 5.15 State the identities of Boolean addition and Boolean multiplication.
Solution : Identities of Boolean addition 1. A+0 = A 2.
A+1 = 1
3.
A+A = A
4. A+A = 1 Identities of Boolean multiplication 1. A×0 = 0 2.
A×1 = A
3. 4.
A×A = A A×A = 0
+
Example 5.16 Prove that AB + A + AB = 0
VTU : Feb.-07, 09, Marks 5
Solution : AB + A + AB = 0 L.H.S. = AB × A × AB
DeMorgan's theorem
A B × A × (A + B)
A + B+ C = A B × C
A B (A + B) AA B+ABB
AA = A A A = 0, B B = 0
0 + 0 = 0 = R.H.S. TM
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5 - 16
Digital Electronics
Example 5.17 i) Prove that AB + A + AB = 0
ii) Simplify Solution : i) AB + A + AB = 0
+
X Y Z+ X Y Z+ X Y+ XY
VTU : Aug.-08, Marks 3
is not true.
AB + A + A B = A (B + 1 + B) Q 1 + A =1
= A ii) X Y Z + X Y Z + X Y + X Y = X Y (Z + Z + 1 ) + X Y = X Y+X Y
Q 1 + A =1
= Y (X + X)
Q A + A=1
= Y Example 5.18
Simplify ABC + ABC + ABC + ABC and realize using basic gates.
+
VTU : Aug.11, Marks 8
Solution : Simplification ABC + ABC + ABC + ABC = AC (B + B) + AB (C + C) + BC (A + 1) = AC + AB + BC Realization A C A B
Y
B C
Fig. 5.7 Example 5.19 Implement EX-OR gate using only NAND gates.
+
Solution : The Boolean expression for EX-OR gate is : Y = AB + AB A B Y A B
Fig. 5.8 (a) TM
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Basic Electronics
5 - 17
Digital Electronics
We can implement AND-OR logic by using NAND-NAND logic as shown in Fig. 5.8 (b). A
A
A B
B
A×B
B
º
Y
A B
A B A×B
Fig. 5.8 (b) Example 5.20 Implement EX-NOR gate using only NAND gates.
Solution : We have, A B
A B
Y
Y EX-OR Inverter
EX-NOR
Fig. 5.9 (a)
Thus using result in previous example we have EX-NOR gate using only NAND gates as shown in the Fig. 5.9 (b) A
A
A×B
B
B
Y A
A×B
B
Fig. 5.9 (b) Example 5.21 Implement EX-OR gate using only NOR gates.
Solution : Boolean expression of EX-OR gate F = AB + AB F = F = AB + AB A B F A B
Fig. 5.10 (a) TM
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Digital Electronics
= (A + B) × (AB) = (A + B) × (A + B)
· Note : We can implement OR-AND logic by NOR-NOR logic.
º
A B F A B
A
A
º
B
B
F
A
A B
B
Fig. 5.10 (b) Example 5.22 Simplify the following 4 variable function using K-map and represent using NAND
gate only : F(A, B, C, D) =
Solution : F (A, B, C, D)
=
( ABC D + ABCD + ABCD + ABCD + AB C D + ABC D ) + d ( A B C D + A B CD + A B CD + AB C D + ABCD + ABCD ) ( AB C D + ABC D + ABCD + ABCD + AB C D + ABC D) + d ( A B C D + A B C D) + A B C D + A B C D + A B C D + A B C D)
f (A, B , C, D) = Sm ( 4,5,6,7,8,12) + d (1, 2, 3, 9, 11, 14). K-map simplification : AB CD 00 00
ACD
01
1
11
1
10
1
01
11
10
X
X
X
1
1
1
AB
X X
X
Fig. 5.11
\
f = AB +AC D TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
5 - 19
Implementation using basic gates
Digital Electronics
Implementation using only NAND gates
A
A
B B
f
A
A
C
C
D
f = (A B) (A C D) D
=AB+ACD =AB+ACD
Fig. 5.12 (a)
Note : AND-OR logic can be implemented by NAND-NAND logic. Example 5.23
Simplify and realize the following using NAND gates A B C + A B C + A B + AC.
Solution : A B C + A B C + A B + AC = B C
(A + A ) + A B + A C
+
VTU : Feb.-10, Marks 5
= B C+ A B+ A C
We can implement AND-OR logic using NAND-NAND logic A
A
B
B
Y C
C
Fig. 5.13 Example 5.24 Draw half adder using NAND gates.
Solution : For half adder : Sum = AB + AB
C out = AB = AB
= AB + AB = A B×A B
TM
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5 - 20
Digital Electronics
AB
A B
A B × A B = Sum AB
AB
A B = A B = Cout
Fig. 5.14 Example 5.25 Realize full adder circuit using NAND gate and write its truth table.
+
VTU : Feb.-08, Marks 8
Solution : We have, Cout = AB + ACin + BCin Sum = A B C in + A B C in + A B C in + A B C in We can implement AND-OR logic using NAND-NAND logic. A B A
Cout
Cin B Cin
A
B
Cin B
Cin
Sum
A A B Cin
Fig. 5.15 TM
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Basic Electronics
5 - 21
Digital Electronics
Multiple Choice Questions with Answers Introduction Q.1
The binary logic used in binary system uses _____ value. (a) only one
(b) only two
(c) three
(d) more than three (Ans. : b)
Switching and Logic Levels Q.1
In ______ logic system, high voltage level is represented by 1 and low voltage level is represented by 0. (a) positive
(b) negative
(c) zero
(d) none of these (Ans. : a)
Digital Waveform Q.1
A _____ is a signal that can have one of a finite set of possible values at any time. (a) digital signal
Q.2
(c) continuous signal (d) none of these (Ans. : a)
An analog signal can have ____ number of possible values. (a) finite
Q.3
(b) analog signal
(b) only one
(c) one of an infinite
(d) cannot be predicted (Ans. : c)
In digital systems number formed by ____ values are used to represent the levels of discrete signal. (a) decimal
(b) octal
(c) hexadecimal
(d) binary
(Ans. : d)
Introduction to Number Systems Q.1
Which numbering system employs only ten digits ? (a) Binary
Q.2
(b) Hexadecimal
Q.4
(d) Octal
(Ans. : c)
The digits that may be used in the unit column of the octal numbering system are : (a) 0 through 15
Q.3
(c) Decimal
(b) 0 through 7
(c) 1 through 10
(d) 1 through 8 (Ans. : b)
To distinguish between numbering systems, one may refer to the : (a) Reset and carry action
(b) Radix
(c) Positional weight
(d) Significant digits
(Ans. : b)
What is the radix for the binary numbering system ? (a) 16
(b) 10
(c) 8
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(d) 2
(Ans. : d)
Basic Electronics
Q.5
1
2
(b) 2
(b) Octal
(b) Seven (b) Byte (b) 11
(c) Nibble
(d) Word
(Ans. : d)
(d) 18
(Ans. : a)
(d) 1
(Ans. : d)
(c) 1001
(d) 1111
(Ans. : a)
Hexadecimal letters A through F are used for decimal equivalent values of : (b) 9 through 14
(c) 10 through 15
(d) 11 through 17 (Ans. : c)
Hexadecimal number F is equal to octal number _______ . (b) 16
(c) 17
(d) 18
(Ans. : c)
(c) 17
(d) 14
(Ans. : a)
(c) 11
(d) 108
(Ans. : c)
(d) none
(Ans. : d)
Binary number 1101 is equal to octal number _______ . (b) 16
Convert binary 1001 to octal _______ . (b) 118
Octal number 12 is equal to decimal number _______ . (a) 8
Q.18
(Ans. : a)
(c) 2
(b) 1101
(a) 98
Q.17
(d) Two
Hexadecimal number E is equal to binary number _______ .
(a) 15
Q.16
(c) Ten
(c) 17
(b) 4
(a) 15
Q.15
(d) 6 digits (Ans. : b)
In a binary number, the column for the LSB is represented by 2 , which has a value of :
(a) 1 through 6
Q.14
(c) 7 digits
0
(a) 1110
Q.13
(d) Hexadecimal (Ans. : d)
In hexadecimal number system, A is equal to decimal number _______ .
(a) 8
Q.12
(Ans. : c)
Which is the longest: bit, byte, nibble, word ?
(a) 10
Q.11
4
The base of the octal system is :
(a) Bit
Q.10
(d) 2
(c) Coded decimal
(b) 8 digits
(a) Eight
Q.9
3
Hexadecimal and octal numbering systems are similar for the first : (a) 9 digits
Q.8
(c) 2
What is a base 16 numbering system called ? (a) Binary
Q.7
Digital Electronics
The positional weight of the binary one in the binary number 001000 is represented by : (a) 2
Q.6
5 - 22
(b) 11
(c) 9
The binary equivalent of the decimal member 5 is _______ . A) 100
B) 101
C) 110
D) 1001.
+
(Ans. : c)
VTU : Feb.-10
Conversion between Decimal, Octal, Hexadecimal and Binary Numbers Q.1
What is 3110 converted to binary ? (a) 110001 (b) 011111
(c) 101011 TM
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(d) 111110 (Ans. : b)
Basic Electronics
Q.2
5 - 23
What is the decimal value of the binary number 111110 ? (a) 30
Q.3
(b) 62 (b) 256
(b) 001100011
Q.13
(d) 110011100 (Ans. : a)
(b) 400
(c) 200
(d) FFF
(Ans. : a)
(b) 010 101 110
(c) 1001010110
(d) 10010101110 (Ans. : c)
(b) 110000001001
(c) 110000001100
(d) 110100001011 (Ans. : a)
(b) 00110101
(c) 00110010
(d) 00110001 (Ans. : c)
The binary equivalent of decimal number 6 is _______ .
(ABC)16 = (?)10 (a) 3000
(b) 011
(c) 110
(b) 4230
(c) 2748
(d) 1001
(d) 2250
+
(Ans. : c)
VTU : Jan.11 (Ans. : c)
+
VTU : Jan.11
+
VTU : Jan.11
(11011)2 = (?)8 (b) (17)8
(c) (25)8
(d) (28)8
(Ans. : a)
The decimal number 20 in hexadecimal code is _______ . (a) 41
Q.15
(c) 111011111
(Ans. : d)
What is the resultant in binary of the decimal problem 49 + 01 = ?
(a) (33)8
Q.14
(d) 1476
Convert hexadecimal C0B to binary.
(a) 100
Q.12
(c) 1388
What is the binary equivalent of octal number 1126 ?
(a) 01010101
Q.11
(d) 100000000 (Ans. : c)
What is the HEX value of a binary 1111111111 ?
(a) 110000001011
Q.10
(Ans. : b)
What is the binary value of 12316 ?
(a) 10110011000
Q.9
VTU : Jan.-14
(d) 8192
(c) 011111010
(b) 12.166
(a) 3FF
Q.8
+
(Ans. : b)
What is the result when a decimal 5238 is converted to base 16 ?
(a) 100100011
Q.7
(c) 4096
(b) 011111101
(a) 327.375
Q.6
(d) 126
What would be the binary result if a HEX value of F9 is added to a HEX 1 ? (a) 011111001
Q.5
(c) 64
With the number 8BF16, what is the positional weight of the 8 ? (a) 16
Q.4
Digital Electronics
(b) 14
(c) 140
(d) 410
(25)10 = (?)2 (a) (00111)2
(b) (11001)2
(c) (11000)2
TM
(d) (00011)2
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+ +
(Ans. : b)
VTU : July-11 (Ans. : b)
VTU : Feb-11
Basic Electronics
Q.16
Q.17
(10101111001 . )2 = (?)16 (a) (AB.2C)16 (b) (2C.B8)16
Q.19
Q.20
(b) 01010
(d) (2C.2D)16
(c) 11100
(d) 11111
(a) (111110011110011100 . )2
(b) (101011001110011001 . )2
(c) (000011110.111100001)2
(d) (010101010.001100110)2
(11011)2 = ( )8 (a) (33)8 (b) (17)8
+
(Ans. : c)
VTU : Feb.-09
+
(Ans. : b)
VTU : Feb.-09
(c) (25)8
(d) (28)8
+ +
(Ans. : a)
VTU : Feb.-09 (Ans. : a)
VTU : Feb.-09
The 2's complement of 1100110 is (b) 0011010
(c) 1100001
(d) 1100010.
+
(Ans. : b)
VTU : Aug.-09
The BCD representation of decimal 10 is _______ . (a) 00001010
Q.22
(c) (2B.C8)16
(763.634)8 = (?)2
(a) 0011001
Q.21
Digital Electronics
2's complement of binary number 10110 is __________. (a) 00011
Q.18
5 - 24
(b) 00001001
(c) 00010000
(d) 10100000.
(Ans. : c)
+
VTU : Aug.-09
+
VTU : Aug.-09
The binary of (A5)16 is _______ . (a) 00100111
(b) 00100101
(c) 10100101
(d) 10100011
(Ans. : c)
Complement of Binary Numbers Q.1
The two's complement of (1 0 0 1)2 is ____. (a) 1001 (b) 0010 (c) 0110
(d) 0111
+
(Ans. : d)
VTU : July-11
Binary Arithmetic Q.1
Q.2
Q.3
F16 + 1F16 in binary is ______. (a) 101111 (b) 101110
(c) 111111
(d) 011111 (Ans. : b)
(31)8 – (25)8 in binary is ______. (a) 10000 (b) 01000
(c) 00100
(d) 00001
+
(64)16 – (46)8 in binary is _______. (a) 111101101
(b) 111101100
(c) 111110
TM
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(Ans. : c)
VTU : Jan.-14
(d) 1100110 (Ans. : c)
Basic Electronics
5 - 25
Digital Electronics
Boolean Algebra Theorems Q.1
_____________ is the mathematical representation used to show the relation between the inputs and the outputs of a gate. (a) Boolean expression (b) Characteristic equation (c) Both
Q.2
______ is the Boolean expression for the EX-NOR gate. (a) Y = A B + A B
Q.3
(b) A B + A B
(c) AB + A B
(Ans. : a)
(b) NOR
(c) OR
(Ans. : a)
(b) EX-NOR
(c) EX-OR
(Ans. : b)
(b) canonical
(c) none of these
(Ans. : a)
(b) two
(c) three
(Ans. : b)
(b) A
(c) 1
(Ans. : a)
(b) A
(c) 1
(Ans. : b)
(b) A
(c) 1
(Ans. : a)
(b) A
(c) 1
(Ans. : a)
(b) A
(c) 0
(Ans. : c)
(b) A+B
(c) A + B
(Ans. : c)
A + ______ = A . (a) 1
Q.16
(Ans. : b)
A× ______ = 0. (a) 0
Q.15
(c) EX-NOR
0 × A = ______. (a) 0
Q.14
(b) EX-OR
A × 1 = ______. (a) 0
Q.13
(Ans. : a)
A × A = ______. (a) 0
Q.12
(c) NOT
Only _______possible values are allowed in Boolean algebra. (a) one
Q.11
(b) NOR
The analysis and simplification of the digital circuits are done using _______algebra. (a) Boolean
Q.10
(Ans. : a)
Y = AB + A B represents ______ gate. (a) OR
Q.9
(c) Y = A B + AB
Y = A + B represents a ______ gate. (a) NAND
Q.8
(b) Y = A B + A B
The output expression of EX-NOR with inputs A and B is ______. (a) A B + A B
Q.7
(Ans. : a)
Y = A B + A B represents ______ gate. (a) OR
Q.6
(c) Y = A + B
The Boolean expression for ______ gate is Y = AB . (a) NAND gate
Q.5
(b) Y = A B + A B
______ is the Boolean expression for the EX-OR gate. (a) Y = A B + A B
Q.4
(Ans. : a)
A + AB = ______. (a) 0
TM
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Basic Electronics
Q.17
5 - 26
A + A B = _________ . (b) A + B
(a) A + B
Q.18
(c) A + B
(Ans. : b)
(c) A + B
(Ans. : a)
A + AB = __________ . (b) B
(a) A + B
Q.19
Digital Electronics
A = A represents __________ law. (a) commutative
(b) associative
(c) distributive
(d) inversion (Ans. : d)
Q.20
DeMorgan's first theorem is _________. (a) A × A = 0
(b) A = A
(c) A + A = A
(d) ( AB) = A + B (Ans. : d)
Q.21
DeMorgan's second theorem is _________. (b) A = A
(a) A × A = 0
(c) (A + B) = A × B
(d) ( AB) = A + B (Ans. : c)
Q.22
According to Boolean algebra which of the following relation is not valid ? (a) X(YZ) = (XY) Z
Q.23
(d) X(X+Y) = 1 (Ans. : d)
Simplify the following expression : F = ABC + AB C + ABC. (a) F = AC + AB
Q.24
(b) X(Y+Z) = XY+XZ (c) X+XZ = X
(b) F = AC + AB
(c) F = AC + AB
(d) F = AC + AB (Ans. : a)
It is required to determine the logical output of the circuit shown in figure, built using NAND gates. Pick up the correct answer. A
Output
B
(a) A × B
(b) A + B
(c) A + B
(d) AB + AB (Ans. : b)
Q.25
The expression AB + BC + BC when simplified is ______. (a) A × B
Q.26
(c) AB + C
(d) none
(Ans. : c)
(c) ( A + B ) × ( C + D)
(d) none
(Ans. : c)
(c) 1
(d) 0
(Ans. : b)
Complement of expression AB + CD is _______. (a) A + B
Q.27
(b) C (b) C + D
Simplify (A + B) (A + B). (a) A
(b) B TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
Q.28
5 - 27
Simplify ABC + ABC + ABC + ABC. (a) A
Q.29
Q.31
(d) A–B
(Ans. : a)
(Ans. : b)
A + AB = ________. (b) A
(c) B
(d) 1 + A
(Ans. : b)
+
VTU : Jan.-11
+
VTU : Jan.-11
The complement of A + B + 1 is ________ . (b) A + B + 1
(c) AB + 1
(d) 1
(Ans. : a)
Simplified form of Boolean expression of 1 + AB is (b) AB
(d) A + B
(c) AB
+
(Ans. : a)
VTU : Aug.-11
Simplified of AB is ______. (b) A + B
(c) A + B
(d) A + B
DeMorgan theorem states that A + B = _________ . (b) A × B
(c) AB
(Ans. : b)
+
VTU : Jan.-14
(d) None.
(Ans. : b)
A + AB + A = _________ . A) AB
Q.37
(c) A+B
(d) NAND gate
(a) A + B
Q.36
(b) B
(c) exclusive OR gate
(a) A + B
Q.35
(Ans. : c)
(b) exclusive NOR gate
(a) 1
Q.34
(d) none
(a) NOR
(a) 0
Q.33
(c) C
The logic expression AB + A B can be implemented by given inputs A and B to a two input _________.
(a) AB
Q.32
(b) B
Simplify Y = AB + AB. (a) A
Q.30
Digital Electronics
B) A + B
C) A
D) 0.
(Ans. : c)
The Boolean expression Y = A.B represents ________ . A) OR gate B) XNOR gate
C) AND gate
D) NOT gate
(Ans. : c)
Logic Gates Q.1
The logical inversion or complement is presented by the _________operator. (a) NOT
Q.2
(Ans. : a)
(b) OR
(c) NAND
(Ans. : b)
The logical ________is presented by the "AND" operator. (a) multiplication
Q.4
(c) NOR
The logical addition is presented by the __________ operator. (a) AND
Q.3
(b) NAND
(b) addition
(c) subtraction
(Ans. : a)
______ are the basic building blocks of all the digital circuits. (a) MUX
(b) Logic gates
(c) Encoders TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
(Ans. : b)
Basic Electronics
Q.5
5 - 28
The electrical symbol illustrated below represents a : _______.
(a) OR gate
Q.6
(b) AND gate
(b) Op-amp
Q.9
Q.10
(d) NAND gate (Ans. : b)
(c) NOR gate
(d) NOT gate (Ans. : d)
The electrical symbol illustrated below represents a : _________.
(a) OR gate
Q.8
(c) NOR gate
The electrical symbol illustrated below represents a : ________.
(a) OR gate
Q.7
Digital Electronics
(b) Op-amp
(c) NOR gate
(d) NOT gate (Ans. : c)
For the electrical symbol illustrated below to represent "0" as it's output, the inputs must be : _________.
(a) one input "on", the other "off".
(b) both inputs "on".
(c) both inputs "off".
(d) first input "off", the second "on". (Ans. : c)
For the electrical symbol illustrated below to represent "0" as it's output, the inputs must be : _________.
(a) one input "1", the other "0".
(b) both inputs "1".
(c) both inputs "0".
(d) the top input "0", the bottom input "1". (Ans. : b)
For the electrical symbol given below to represent "1" as it's output, the inputs must be : _________.
(a) one input "1", the other "0".
(b) both inputs "1"
(c) both inputs "0".
(d) the top input "0", the bottom input "1". (Ans. : c) TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
Basic Electronics
Q.11
5 - 29
Digital Electronics
The output of OR gate is logic zero when _________. (a) any one input is logic 1
(b) two inputs are logic 1
(c) all inputs are logic 0
Q.12
(a) high
Q.13
(Ans. : c)
When all the inputs of a NAND gate are zero, the output of it is ______. (b) low
(c) none
(Ans. : a)
For a three input NAND gate the output is 0 only when _______ . (a) all inputs logic 1
(b) all inputs logic 0
(c) any one input logic 1
Q.14
Q.15
For EX-NOR gate the output is 1 if ________ . (a) even number of inputs is 0
(b) even number of inputs is 1
(c) odd number of inputs is 0
(d) odd number of inputs is 1
Q.19
Q.20
Q.23
(b) NOR
(c) NAND
(Ans. : a)
(b) gates
(c) states
(d) none
(b) one input and one output
(c) one input and two outputs
(d) none of above
An OR gate has _________. (a) two inputs and one output
(b) one input and one output
(c) one input and two outputs
(d) none of above
(Ans. : c)
(Ans. : b)
(Ans. : a)
Logic states can only be _____ or 0. (b) 2
(c) 1
(d) 0
(Ans. : c)
(d) NOT
(Ans. : c)
The output of a _____ gate is only 1 when all of its inputs are 1. (a) NOR
Q.22
(Ans. : b)
A NOT gate has _________. (a) two inputs and one output
(a) 3
Q.21
(c) NAND
The output of a logic gate can be one of two ______ . (a) inputs
Q.18
(b) NOR
A ______ gate represents a complement function. (a) NOT
Q.17
(Ans. : b)
______ gate output is logic 1 if and only if all its inputs are logic 0. (a) OR
Q.16
(Ans. : a)
(b) EX-OR
(c) AND
The output of a two-input NOR gate is high _________. (a) only if both the inputs are high (b) only if both the inputs are low (c) only if one input is high and the other is low (d) if at least one of the inputs is high
(Ans. : b)
An XOR gate gives a high output _________. (a) if there are odd number of 1's in the input (b) if there are even number of 1's in the input (c) if there are odd number of 0's in the input (d) if there are even number of 0's in the input TM
TECHNICAL PUBLICATIONS - An up thrust for knowledge
(Ans. : a)
Basic Electronics
Q.24
5 - 30
Digital Electronics
An exclusive NOR gate is logically equal to _________. (a) inverter followed by an XOR gate (b) NOT gate followed by an exclusive OR gate (c) exclusive OR gate followed by an inverter (d) complement of a NOR gate
Q.25
Q.26
(Ans. : c)
The gate ideally suited for bit comparison is a _________. (a) two input exclusive NOR gate
(b) two input NOR gate
(c) two input NAND gate
(d) two input exclusive OR gate
(Ans. : a)
Two input exclusive NOR gate gives high output _________. (a) when one input is high and the other is low (b) only when both the inputs are low (c) when both the inputs are same (d) only when both the inputs are high
Q.27
A table that contains all the possible combinations of the inputs and the corresponding state of output of a logic gate is called ___________. (a) truth table
Q.28
Q.29
(b) excitation table
A
B
Y
0
0
0
0
1
1
1
0
1
1
1
1
Q.32
(Ans. : a)
(a) An exclusive OR gate
(b) A two-input AND gate
(c) A two-input OR gate
(d) An exclusive NOR gate
(Ans. : c)
For a two input EX-OR gate the output is 1 when _______ . (b) AB = 11
(c) AB = 01
(Ans. : c)
For a two input EX-OR gate the output is 0 when ________ . (a) both inputs are equal
Q.31
(c) transition table
Which logic gate has the following truth table ?
(a) AB = 00
Q.30
(Ans. : c)
(b) both inputs are not equal
(Ans. : a)
For EX-OR gate Y = 1 if ––––––– . (a) odd number of inputs are 1
(b) even number of inputs are 1
(c) odd number of inputs are 0
(d) even number of inputs are 0
(Ans. : a)
The output is high only when both the inputs are zero to a gate. The gate is (a) AND
(b) NOR
(c) OR
TM
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(d) NAND
+
(Ans. : b)
VTU : Jan.-11
Basic Electronics
Q.33
(c) OR
(d) NAND
+
(Ans. : d)
VTU : Jan.-11
(b) AB + BA
(c) A B
(d) none of these (Ans. : d)
The output is high when all the inputs are high, such a gate is called ______ . (a) NAND
Q.36
(b) AND
Expression for EX-OR gate with inputs 'A' and 'B' is _______. (a) A + B
Q.35
Digital Electronics
Universal gate is _______. (a) NOT
Q.34
5 - 31
(b) NOR
(c) AND
(d) OR.
(Ans. : c)
For which gate when the two inputs A and B are equal the output is zero and otherwise VTU : Jan.-14 one ?
+
(a) NAND
(b) NOR
(c) EXNOR
(d) EXOR
(Ans. : d)
NAND and NOR Implementation Q.1
The logical addition is presented by the __________ operator. (a) AND
Q.2
(b) OR
(c) NOR
(Ans. : a)
(b) NOT
(c) EX-OR
(d) None
(Ans. : b)
The ______ and ______ gates are known as "Universal Gates". (a) NAND, NOR
Q.5
(Ans. : b)
A NAND gate is equivalent to an AND gate plus a _____ gate put together. (a) NOR
Q.4
(c) NAND
Y = A × B × C represents a ______ gate. (a) AND
Q.3
(b) OR
(b) NAND, EX-OR
(c) OR, AND
(Ans. : a)
A NAND gate is called a universal logic element because _________. (a) it is used by everybody (b) any logic function can be realized by NAND gates alone (c) all the minimization techniques are applicable for optimum NAND gate realization (d) many digital computers use NAND gates
Q.6
(Ans. : b)
In order for output 'Y' to be a "1", inputs A, B and C must be : A B Y
C
Q.7
(a) A = 1, B = 0, C = 0
(b) A = 0, B = 0, C = 0
(c) A = 1, B = 0, C = 1
(d) A = 0, B = 1, C = 0
(Ans. : c)
Which of these are universal gates ? (a) Only NOR
(b) Only NAND
(c) Both NOR and NAND
(d) NOT, AND, OR TM
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(Ans. : c)
Basic Electronics
Q.8
5 - 32
Digital Electronics
+
Universal gates are _____ and ________ . (a) NOT and NOR
B) AND and OR
C) NAND and NOR
D) EXOR and EX-NOR
VTU : Jan.-14 (Ans. : c)
NAND-NAND Implementation Q.1
The NAND-NAND logic is equivalent to _______. (a) AND-NOT logic
(b) AND-OR logic
(c) OR-AND logic
(d) NOT-OR logic (Ans. : b)
NOR-NOR Implementation Q.1
The NOR-NOR logic is equivalent to ___________. (a) AND-OR logic
(b) NOT-AND logic
(c) OR-NOT logic
(d) OR-AND logic (Ans. : d)
Half Adder and Full Adder Q.1
To add two m-bit number, the number of required half adders is __________ . (a) 2m – 1
Q.2
Q.5
(b) carry 0, sum 1
(d) carry 1, sum 1 (Ans. : d)
(d) none of above
A half adder has ––––––– inputs and –––––––– outputs. (b) 1, 2
(c) 2, 1
(Ans. : b)
+ (d) 2, 2
VTU : Jan.-14 (Ans. : d)
The addition of two bits is performed by using a ______ adder. (b) full
(c) parallel
(Ans. : a)
The sum and carry output of H.A. are 1 and 0, then its inputs are_______. (b) 0, 1
(c) 1, 0
(d) 1, 1
(Ans. : a)
The addition of three bits is performed by using a ______ adder. (b) full
(c) flip-flop
(Ans. : b)
In half adder the addition is limited to ___ bits. (a) 2
Q.10
(c) carry 1, sum 0
(c) half of a NAND gate
(a) half
Q.9
(d) carry 1, sum 1 (Ans. : c)
(b) a circuit to add two bits together
(a) both (b) and (c)
Q.8
(c) carry 1, sum 0
(a) half of an AND gate
(a) half
Q.7
(b) carry 0, sum 1
Half adder circuit is ______ .
(a) 1, 1
Q.6
(d) 2m + 1 (Ans. : a)
The result of binary addition 1 + 1 + 1 is ––––––– . (a) carry 0, sum 0
Q.4
– 1
(c) 2
The result of binary addition 1 + 1 is ––––––– . (a) carry 0, sum 0
Q.3
m
(b) 2m
(b) 3
(c) 4
Sum output of half adder is = ___________ . TM
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(Ans. : a)
Basic Electronics
(a) A B + A B
Q.11
Q.16
Q.18
Q.19
(Ans. : b)
(b) 3
(c) 4
(Ans. : b)
(b) EX-NOR
(c) OR
(Ans. : a)
(b) EX-OR
(c) AND
(Ans. : c)
(a) 3 full adders
(b) 2 full adders and 1 half adder
(c) 1 full adder and 2 half adders
(d) 3 half adders
(Ans. : b)
The number of inputs and outputs in a full adder are _________. (b) 2 and 2
(c) 3 and 3
(d) 3 and 2 (Ans. : d)
A full adder can be realized using : _________. (a) one half-adder, two OR gates
(b) two half-adders, one OR gate
(c) two half-adders, two OR gates
(d) none of these
(Ans. : b)
Which of the following is known as half-adder ? (a) EX-OR gate
(b) EX-NOR gate
(c) NAND gate
(d) NOR gate
(Ans. : a)
The half adder circuit has input AB = 11. The logic levels of the S and C outputs will be _________. (a) S = 1, C = 1
Q.20
(c) A B + AB
A 3 bit binary adder should be _________.
(a) 2 and 1
Q.17
(b) A B
A half adder circuit is constructed by using 2-input EX-OR gate and 2-input _____ gate. (a) EX-NOR
Q.15
(Ans. : a)
A half addition i.e. addition of two-bits can be achieved using ______ gate. (a) EX-OR
Q.14
(c) A B + AB
The full adder can perform addition of ________ bits. (a) 2
Q.13
(b) AB
Digital Electronics
Carry output of half adder is = ____________ . (a) A B + A B
Q.12
5 - 33
(b) S = 0, C = 0
(c) S = 1, C = 0
(d) S = 0, C = 1 (Ans. : a)
(c) 3
(d) 4
Full adder has _______ inputs. (a) 1
b) 2
+
(Ans. : c)
VTU : Aug.-11
qqq
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Notes
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Digital Electronics
6
Flip-Flops
Chapter at a Glance Important Definitions 1.
What is flip-flop ?
· Flip-flop is a bi-stable digital circuit, i.e., its outputs have two stable states : logic 1 and logic 0.
One or more inputs
Q Outputs
CLK input Q
· It is a sequential circuit; it requires a clock signal to be applied at its inputs for operation. · The Fig. 6.1 shows the block diagram of a flip-flop. It has one or more inputs, two outputs and a clock input. · The Fig. 6.2 shows the clock signal. It is a rectangular signal with 50 % duty cycle.
Fig. 6.1 Flip-flop
High
Leading edge
Low
Falling edge Time
· The flip-flop changes its outputs either at Fig. 6.2 the leading edge of the clock signal or at the falling edge of the clock signal according to the status of flip-flop input present at that time. · The two outputs of flip-flop Q and Q always complements of each other. 2. Gated SR latch :
· It can easily be modified to create a latch that is sensitive to these inputs only when an enable input is active. Such a latch with enable input is known as gated SR latch.
Important Questions and Answers
Ø
Explain the working of NAND gate latch and NOR gate latch.
One-Bit Memory Cell · The Fig. 6.3 shows the basic bistable element used in latches and flip-flops.
· The basic bistable element has two outputs Q and Q. (6 - 1) TM
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6-2
A
1
B
2
A
B
(a) NOT gate latch
Flip-Flops
Q
A
1
Q
A
1
Q
Q
B
2
Q
B
2
Q
(b) NAND gate latch
(c) NOR gate latch
Fig. 6.3 Gated Latch
· It has two cross-coupled inverters, i.e., the output of the first inverter is connected as an input to the second inverter and the output of second inverter is connected as an input to the first inverter. · The basic bistable element circuit has two stable states logic 0 and logic 1, hence the name 'bistable'. · When A = 0, the output of inverter 1 is 1 (A), i.e., Q = 1. · Since the output of inverter 1 is the input to the inverter 2, A = B = 1. Consequently, the output of inverter 2, i.e., B is 0. · Since the output of the inverter 2 is connected to the input of the inverter 1, Q = B = A = 0. · We have assumed same value for A. Thus, the circuit is stable with Q = A = B = 0 and Q = A = B = 1. · Using similar explanation it is easy to show that if it is assumed that A = 1, the basic bistable element is stable with Q = A = B = 1 and Q = A = B = 0. This is a second stable condition of the basic bistable element. · The two stable states of basic bistable elements are used to store two binary elements, 0 and 1. · In positive logic system, state Q = 1 is used to store logic 1, and state Q = 0 is used to store logic 0. · Two outputs are complementary. That is when Q = 0, Q = 1; and when Q = 1, Q = 0. Important Points 1. The outputs Q and Q are always complementary. 2. The circuit has two stable states. The state corresponds to Q = 1 is referred to as 1 state or set state and state corresponds to Q = 0 is referred to as 0 state or Reset state. 3. If the circuit is in the set (1) state, it will remain in the set state and if the circuit is in the reset (0) state, it will remain in the reset state. This property of the circuit
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Flip-Flops
shows that it can store 1-bit of digital information. Therefore, the circuit is called a 1-bit memory cell. 4. The 1-bit information stored in the circuit is locked or latched in the circuit. Therefore, this circuit is also referred to as a latch.
Ø
Differentiate between latches and flip-flops.
· Latches and flip-flops are the basic building blocks of the most sequential circuits. · The main difference between latches and flip-flops is in the method used for changing their state. · A simple latch forms the basis for the flip-flop. · Latches are controlled by enable signal, and they are level triggered, either positive level triggered or negative level triggered. · The output state is free to change according to the S and R input values, when active level is maintained at the enable input. · Flip-flops are pulse or clock edge triggered instead of level triggered.
Multiple Choice Questions with Answers Introduction Q.1
Which of the following is a bistable logic circuit ? (a) Decoder
(b) Multiplexer
(c) De-Multiplexer
(d) Flip-Flop (Ans. : c)
Q.2
How many stable states do flip flops have ? (a) 0
(b) 1
(c) 2
(d) 3 (Ans. : c)
Q.3
NAND gates act as _______ in the circuit shown in Fig. 6.4.
Fig. 6.4 (a) AND gate
(b) OR gate
(c) INV gate
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(d) none of these (Ans. : c)
Basic Electronics
Q.4
6-4
Flip-Flops
Fig. 6.5 shows _______ .
Fig. 6.5 (a) inverter
(b) cross-coupled inverter
(c) flip-flop
(d) none of these (Ans. : b)
Q.5
The basic bistable element stores ______ bit information. (a) 0
(b) 1
(c) 2
(d) 3 (Ans. : b)
SR Latch / RS Latch Q.1
What does Fig. 6.6 show ? S (set)
1
3
Q
R (Reset)
2
4
Q
Fig. 6.6 (a) Cross coupled inverter
(b) 1-bit memory cell
(c) SR Latch
(d) SR flip-flop (Ans. : c)
Q.2
In SR latch S = R = 0 ______ . (a) 1 and 0
(b) 0 and 1
(c) no change in states
(d) undefined (Ans. : c)
Q.3
Which of the following condition is avoided in SR latch ? (a) S = R = 0
Q.4
(b) S = R = 1
(c) S = 1 and R = 0 (d) None of these (Ans. : b)
If enable input EN = _______ , gated SR latch will operate otherwise there is no change. (a) 1
(b) 0
(c) 1 or 0
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(d) None of these (Ans. : a)
Basic Electronics
Q.5
6-5
Flip-Flops
In gated SR latch if S = _______, R = _______ and E = _______, indeterminate state occurs. (a) 1, 1, 1
(b) 1, 0, 1
(c) 0, 1, 1
(d) 1, 0, 0 (Ans. : a)
Gated SR Latch Q.1
A latch with _____ input is known as gated RS latch. (a) disable
(b) clock
(c) enable
(d) both (a) and (b) (Ans. : c)
Latches Vs. Flip-flops Q.1
A flip-flop is a _________. (a) combinational circuit
(b) memory element
(c) arithmetic element
(d) memory or arithmetic (Ans. : b)
Q.2
–––––– is also known as 1-bit memory cell. (a) Flip-flop
(b) Register
(c) Gate (Ans. : a)
Q.3
The condition S = 0, R = 1 (a) resets
_______ the output of flip-flop.
(b) sets
(c) no change in (Ans. : a)
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Notes
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Flip-Flops
Microprocessors and Microcontrollers
7
Chapter at a Glance Important Definitions 1.
Introduction to Microprocessor 1. Program Counter : The program counter gives the address of memory location from where the next instruction is to be fetched. 2. Instruction Register : Instruction read from memory is loaded into the instruction register. It is then send to the instruction decoder. The instruction decoder decodes the instruction and gives decoded signals as an input to the control unit. 3. Arithmetic Logic Unit (ALU) : The ALU of the microprocessor performs arithmetic and logic operations such as add, subtract, AND, OR, exclusive-OR, complement, shift right, shift left and so on. 4. A Register (Accumulator) : In most of the microprocessors register A gives data for the ALU and after performing the operation, the resulting data word is sent to the register A and stored there. This special register, where the result is accumulated is commonly known as accumulator. 5. Status Register : The status register is used to store the results of certain condition such as result is zero, negative etc., when certain operations are performed during execution of the program. The status register is also referred to as flag register. 6. Control Unit : The control unit is responsible for working of all other parts of the microprocessor together. It maintains the synchronization in operation of different parts in the microprocessor. The control unit receives the signal from instruction decoder and generates the control signals necessary to carry out the instruction execution. 7. Bus : A microprocessor communicates with memory and I/O devices with a common communication path called bus. There are three types of buses : address bus, data bus and control bus.
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Microprocessors and Microcontrollers
8. Stack Pointer (SP) : The stack is a reserved area of the memory in the RAM where temporary information may be stored. A 16-bit stack pointer is used to hold the address of the most recent stack entry in 8085 microprocessor. 9. Special Function Registers (SFRS) : The group of registers, implemented to perform special functions and are located immediately above the 128 bytes of RAM are called special function registers. 10. Stack : The stack refers to an area of internal RAM that is used to store and retrieve data quickly. 11. Top of Stack : The stack pointer register is used by the 8051 to hold an internal RAM address that is called top of stack.
Important Questions and Answers
Ø
Explain architectural features of 8085.
The features of 8085 include : 1. It is an 8-bit microprocessor i.e. it can accept, process, or provide 8-bit data simultaneously. 2. It operates on a single + 5 V power supply connected at VCC; power supply ground is connected to Vss. 3. It operates on clock cycle with 50 % duty cycle. 4. It has on chip clock generator. This internal clock generator requires tuned circuit like LC, RC or crystal. The internal clock generator divides oscillator frequency by 2 and generates clock signal, which can be used for synchronizing external devices. 5. It can operate with a 3 MHz clock frequency. The 8085A-2 version can operate at the maximum frequency of 5 MHz. 6. It has 16 address lines, hence it can access (2 16 ) 64 kbytes of memory. 7. It provides 8-bit I/O addresses to access (28 ) 256 I/O ports. 8. In 8085, the lower 8-bit address bus (A 0 - A 7 ) and data bus (D0 - D7 ) are multiplexed to reduce number of external pins. But due to this, external hardware (latch) is required to separate address lines and data lines. 9. It supports 74 instructions with the following addressing modes : a) Immediate
b) Register
c) Direct
d) Indirect
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Microprocessors and Microcontrollers
10. The Arithmetic Logic Unit (ALU) of 8085 performs : a) 8-bit binary addition with or without carry. b) 16-bit binary addition.
c) 2 digit BCD addition.
d) 8-bit binary subtraction with or without borrow. e) 8-bit logical AND, OR, EX-OR, complement (NOT), and bit shift operations. 11. It has 8-bit accumulator, flag register, instruction register, six 8-bit general purpose registers (B, C, D, E, H and L) and two 16-bit registers (SP and PC). Getting the operand from the general purpose registers is more faster than from memory. Hence skilled programmers always prefer general purpose registers to store program variables than memory. 12. It provides five hardware interrupts : TRAP, RST 7.5, RST 6.5, RST 5.5 and INTR. 13. It has serial I/O control which allows serial communication. 14. It provides control signals (IO/M, RD, WR) to control the bus cycles and hence external bus controller is not required. 15. The external hardware (another microprocessor or equivalent master) can detect which machine cycle microprocessor is executing using status signals (IO/M, S0, S1). This feature is very useful when more than one processors are using common system resources (memory and I/O devices). 16. It has a mechanism by which it is possible to increase its interrupt handling capacity. 17. The 8085 has an ability to share system bus with direct memory access controller. This feature allows to transfer large amount of data from I/O device to memory or from memory to I/O device with high speeds. 18. It can be used to implement three chip microcomputer with supporting I/O devices like IC 8155 and IC 8355.
Ø
Give the comparison between microprocessor and microcontroller.
Sr. No.
Microprocessor
Microcontroller
1.
Microprocessor contains ALU, control unit (clock and timing circuit), different register and interrupt circuit.
Microcontroller contains microprocessor, memory (ROM and RAM), I/O interfacing circuit and peripheral devices such as A/D converter, serial I/O, timer etc.
2.
It has many instructions to move data between memory and CPU.
It has one or two instructions to move data between memory and CPU.
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Microprocessors and Microcontrollers
3.
It has one or two bit handling instructions.
It has many bit handling instructions.
4.
Access times for memory and I/O devices are more.
Less access times for built-in memory and I/O devices.
5.
Microprocessor based more hardware.
Microcontroller based system requires less hardware reducing PCB size and increasing the reliability.
6.
Microprocessor based system flexible in design point of view.
7.
It has single memory map for data and code.
It has separate memory map for data and code.
8.
Less number of pins are multifunctioned.
More number pins are multifunctioned.
system
requires
is
more
Less flexible in design point of view.
What are the main features of 8051 microcontroller ?
The features of the 8051 family are as follows : 1. 4096 bytes on - chip program memory. 2. 128 bytes on - chip data memory. 3. Four register banks. 4. 128 user-defined software flags. 5. 64 kilobytes each program and external RAM addressability. 6. One microsecond instruction cycle with 12 MHz crystal. 7. 32 bidirectional I/O lines organized as four 8-bit ports (16 lines on 8031). 8. Multiple mode, high-speed programmable serial port. 9. Two multiple mode, 16-bit timers/counters. 10. Two-level prioritized interrupt structure. 11. Full depth stack for subroutine return linkage and data storage. 12. Direct byte and bit addressability. 13. Binary or decimal arithmetic. 14. Signed-overflow detection and parity computation. 15. Hardware multiple and divide in 4 msec. 16. Integrated boolean processor for control applications. 17. Upwardly compatible with existing 8084 software.
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Ø Ø
7-5
Microprocessors and Microcontrollers
1. Explain the operation of stack in 8051. 2. Define SP.
The stack refers to an area of internal RAM that is used to store and retrieve data quickly. The stack pointer register is used by the 8051 to hold an internal RAM address that is called top of stack. The stack pointer register is 8-bit wide. It is increased before data is stored during PUSH and CALL instructions and decremented after data is restored during POP and RET instructions. The stack array can reside anywhere in on-chip RAM. The stack pointer is initialized to 07H after a reset. This causes the stack to begin at location 08H. The operation of stack and stack pointer is illustrated in Fig. 7.1. On-chip RAM
On-chip RAM
08 07 06 SP
SP Stack pointer
09 08 07
(a) Status of stack and stack pointer of reset
SP Stack pointer
Data 1 Data 2 Data 3
On-chip RAM
Data SP
SP+1
09 08 07
(b) Store operation
09 08 07
Data 2 Read
SP
09 08 07
SP–1
(c) Read operation
Fig. 7.1
The stack may overwrite data in the register banks, bit-addressable RAM and scratch-pad RAM. Thus to avoid conflict with the register, bit-addressable RAM and scratch-pad RAM data, the stack is initialized at a higher location in the internal RAM.
Multiple Choice Questions with Answers Introduction to Microprocessor Q.1
The microprocessor consists of __________ . (a) SP
Q.2
(b) ALU
(c) PC
(d) All of these (Ans. : d)
___________ is not a part of microprocessor. (a) ALU
(b) Control unit
(c) Memory and I/O devices (Ans. : c) TM
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Q.3
7-6
Microprocessors and Microcontrollers
A microprocessor chip performs the function of _________. (a) ROM
(b) RAM
(c) peripheral devices (d) control unit and ALU (Ans. : d)
Q.4
A microprocessor is called an n-bit microprocessor depending on _________. (a) number of registers
(b) size of data bus
(c) size of address bus
(d) none of these (Ans. : b)
Q.5
ALU stands for_________ . (a) arithmetic logic unit
(b) array logic unit
(c) none of these. (Ans. : a)
Q.6
Which parts of the computer perform arithmetic calculations ? (a) ALU
Q.7
(b) Registers
(c) Logic bus
(d) None of above (Ans. : a)
The _______ performs all the computations in a microprocessor. (a) ALU
(b) control unit
(c) register array (Ans. : a)
Q.8
The accumulator's main purpose is _________. (a) temporary data storage (b) keeping track of the next instruction to be executed (c) selecting which peripheral should be addressed (d) storing instructions (Ans. : a)
Q.9
Generally result is accumulated in _______ register. (a) accumulator
(b) SP
(c) PC (Ans. : a)
Q.10
The CPU stands for ________ . (a) central processing unit
Q.11
(b) control processing unit
(c) central process unit (Ans. : a)
Microprocessor communicates with the outside world through the __________ . (a) memory
(b) I/O devices
(c) ALU (Ans. : b)
Q.12
_________ register gives the address of the memory location from where the next instruction is to be fetched. (a) Accumulator
(b) SP
(c) PC (Ans. : c)
Q.13
Program counter is used to _________. (a) store address of the next instruction to be executed (b) store temporary data to be used in arithmetic operations TM
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Microprocessors and Microcontrollers
(c) store the status of the microprocessor (d) none of these (Ans. : a)
Architecture of 8085 Q.1
8085 is an ____ bit microprocessor. (a) 8
(b) 12
(c) 16
(d) 32 (Ans. : a)
Q.2
8085 is a microprocessor _____. (a) single chip
Q.3
(c) multi chip
(d) both (a) and (c) (Ans. : a)
(c) NMOS
(d) None of these (Ans. : c)
8085 is a _____ device. (a) CMOS
Q.4
(b) double chip
(b) PMOS
8085 microprocessor is ____ pin dual-in-line package. (a) 40
(b) 20
(c) 30
(d) 28 (Ans. : a)
Q.5
For 8085, VCC is ______. (a) + 5 V
(b) – 5 V
(c) ± 5 V
(d) + 6 V (Ans. : a)
Q.6
For 8085, VSS is ______. (a) + 5 V
(b) – 5 V
(c) GND
(d) – 6 V (Ans. : c)
Q.7
Which of the following microprocessor is an 8 bit microprocessor ? (a) 8051
(b) 8086
(c) 68000
(d) 8085 (Ans. : d)
Q.8
An 8-bit microprocessor signifies that it has ____. (a) an 8 bit address bus
(b) an 8 bit control bus
(c) 8 interrupt lines
(d) an 8 bit data bus (Ans. : d)
Q.9
A microprocessor is capable of addressing 64 kbytes of memory. Its address bus width is ____. (a) 8
(b) 12
(c) 16
(d) 20 (Ans. : c)
Q.10
8085 has a clock cycle with ____ duty cycle. (a) 20 %
(b) 40 %
(c) 50 %
(d) 60 % (Ans. : c)
Q.11
8085 has ____ address lines. (a) 14
(b) 15
(c) 16
(d) 18 (Ans. : c)
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Q.12
Microprocessors and Microcontrollers
8085 can access ____ of memory. (a) 64 kbits
Q.13
7-8
(b) 64 kbytes
(c) 64 Mbits
(d) 64 Mbytes (Ans. : b)
(c) 8 byte
(d) 16 byte
8085 has _____ I/O addresses. (a) 8 bit
(b) 16 bit
(Ans. : a)
Q.14
8085 can access ____ I/O ports. (a) 252
(b) 254
(c) 255
(d) 256 (Ans. : d)
Q.15
8085 supports ____ instructions. (a) 76
(b) 75
(c) 72
(d) 74 (Ans. : d)
Q.16
Q.17
If a processor is capable of addressing 2 Mbytes of memory, its data bus width is ____. (a) 8
(b) 16
(c) 16
(d) cannot be predicted (Ans. : d) A number of 1 bit registers used in 8085 to indicate certain conditions are usually referred to as _____.
(a) flags
(b) shift registers
(c) counters
(d) latches (Ans. : a)
Q.18
A microprocessor performs the same functions as ____. (a) memory of a computer
(b) CPU of a computer
(c) output device of a computer
(d) input device of a computer (Ans. : b)
Q.19
A microprocessor is a ___. (a) LSI device
Q.20
(c) both (a) and (b)
(d) none of these (Ans. : a)
W and Z registers of 8085 are _____ registers. (a) temporary
Q.21
(b) MSI device
(b) general purpose
(c) special purpose
(d) sixteen bit (Ans. : a)
_______ is temporary register. (a) Accumulator
(b) Flag registers
(c) Temporary data register
(d) Stack pointer (Ans. : c)
Q.22
Accumulator is a ____ register. (a) general purpose
(b) temporary
(c) special purpose
(d) 16 bit (Ans. : c)
Q.23
Flag register is a _____ register. (a) 16 bit
Q.24
(b) general purpose
(c) temporary
(d) special purpose (Ans. : d)
PC in a microprocessor ____. (a) counts the number of programs being executed by the microprocessor. (b) counts the number of interrupts handled by the microprocessor. TM
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7-9
Microprocessors and Microcontrollers
(c) holds the address of next instruction that is to be executed. (d) all of the above (Ans. : c)
Q.25
If a microprocessor has an 8 bit opcode. The maximum possible number of opcodes for this microprocessor will be ____. (a) 266
(b) 200
(c) 256
(d) 486 (Ans. : c)
Q.26
PC is a _____ register. (a) general purpose
(b) 16 bit
(c) special purpose
(d) b and c (Ans. : c)
Q.27
_____ is a 16 bit register. (a) Temporary data register
(b) W register
(c) Stack pointer
(d) Flag register (Ans. : c)
Pin Diagram of 8085 Q.1
SOD means _____. (a) Single Output Data
(b) Serial Output Data
(c) Standard Output Data
(d) none of the above (Ans. : b)
Q.2
SID means _____. (a) Single Input Data
(b) Serial Input Data
(c) Standard Input Data
(d) none of the above (Ans. : b)
Q.3
______ is used to send data serially. (a) SOD
(b) SD
(c) SID
(d) SRD (Ans. : a)
Q.4
_____ is used to receive data serially. (a) SOD
(b) SID
(c) STD
(d) SD (Ans. : b)
Q.5
In 8085, internal clock generator divides the oscillator frequency by _____. (a) 4
(b) 6
(c) 2
(d) 8 (Ans. : c)
Q.6
_____ signal of 8085 is used as a system clock for other devices. (a) X1
Q.7
(b) X2
(c) CLK OUT
(d) None of these (Ans. : c)
CLK OUT frequency is ____ of the oscillator frequency. (a) half
(b) double
(c) quadraple
(d) thrice (Ans. : a)
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Q.8
7 - 10
Microprocessors and Microcontrollers
ALE means _____. (a) Address Latch Enable
(b) Access Latch Enable
(c) Address Latch Error
(d) Access Latch Error (Ans. : a)
Q.9
When ____ , data is read from the selected memory location or I/O device port via data bus. (a) RD = 1
(b) RD = 0
(c) WR = 1
(d) WR = 0 (Ans. : b)
Q.10
The data bus in a mP based system is used for data transfer _____. (a) between the mP and I/O devices
(b) between the mP and memory
(c) between the I/O devices and memory
(d) for all of the above (Ans. : d)
Q.11
When _____ , the data is written into the selected memory location or I/O port via data bus. (a) WR = 1
(b) RD = 1
(c) WR = 0
(d) RD = 0 (Ans. : c)
Q.12
In 8085, _____ indicates whether I/O operation or memory operation is carried out. (a) RD
(b) WR
(c) IO M
(d) READY (Ans. : c)
Q.13
In 8085, _____ signal is used to check whether the peripherals are ready or not for data transfer. (b) S0 and S1
(a) IO M
(c) RD
(d) READY (Ans. : d)
Q.14
INTA means ____. (a) Interrupt Address
(b) Interrupt Accept
(c) Interrupt Access
(d) Interrupt Acknowledge (Ans. : d)
Q.15
In 8085, _____ signal indicates that another master is requesting for access of address bus, data bus and control bus. (a) HLDA
(c) HOLD
(b) RESET IN
(d) SID (Ans. : c)
Q.16
In mP 8085, HLDA is active _____ signal. (a) High
Q.17
(b) Low
(c) not defined
(d) none of these (Ans. : a)
_____ is used to acknowledge HOLD request. (a) INTA
(b) HOLD
(c) HLDA
(d) SOD (Ans. : c)
Q.18
PC = 0000H when _____. (a) RESET IN = 1
(b) RESET OUT = 1 (c) RESET IN = 0
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(d) RESET OUT = 0 (Ans. : c)
Basic Electronics
Q.19
7 - 11
Microprocessors and Microcontrollers
In 8085, for proper reset operation, reset signal must be held low for at least ____ clock cycles. (a) 4
(b) 3
(c) 2
(d) 1 (Ans. : b)
Q.20
RESET OUT is active ____ signal. (a) High
Q.21
(b) Low
(c) input
(d) none of these (Ans. : a)
____ signal indicates that 8085 is being reset. (a) HOLD
(b) HLDA
(c) RESET IN
(d) RESET OUT (Ans. : d)
Bus Organization Q.1
The built-in clock generator of 8085 consist of internal T flip-flop that ____. (a) divides frequency by 2
(b) divides frequency by 4
(c) multiplies frequency by 2
(d) multiplies frequency by 4 (Ans. : s)
Q.2
The operating frequency of 8085 is always _____ the oscillator frequency. (a) thrice of
(b) twice of
(c) same as
(d) half of (Ans. : d)
Q.3
IC 74LS373 is _______ latch. (a) an 8 bit
(b) 16-bit
(c) 32 bit
(d) 64 bit (Ans. : a)
Q.4
In the reset circuit of 8085, at power on, ______ pin goes low. (a) RESET IN
(b) RESET OUT
(c) RESET IN
(d) RESET OUT (Ans. : c)
Introduction to Microcontroller Q.1
The __________ includes microprocessor, memory and I/O on a single chip. (a) microprocessor
(b) microcomputer
(c) microcontroller (Ans. : c)
Q.2
_________ holds the opcode of the instruction. (a) IR
(b) SP
(c) PC (Ans. : a)
Q.3
In _____________, more number of pins are multifunctional. (a) microprocessor
(b) microcontroller
(c) none of these (Ans. : b)
Q.4
The microcontroller has built-in ______________. (a) ROM
(b) parallel I/O
(c) serial I/O
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(d) all of these (Ans. : d)
Basic Electronics
7 - 12
Microprocessors and Microcontrollers
Introduction to 8051 Microcontroller Q.1
The 8051 is _____ microcontroller. (a) 32 bits
(b) 16 bits
(c) 12 bits
(d) 8 bits (Ans. : d)
Q.2
The 8051 microcontroller was designed by _____. (a) Intel
(b) Microsoft
(c) Motorola
(d) IBM (Ans. : a)
Q.3
8051 has ______ on-chip program memory. (a) 1024 bytes
Q.4
(b) 4096 bytes
(c) 2048 bytes
(d) 4096 bits (Ans. : b)
(c) 128 bytes
(d) 128 bits
8051 has ______ on-chip data memory. (a) 256 bytes
(b) 256 bits
(Ans. : c)
Architecture of 8051 Q.1
8051 has ______ register banks. (a) 2
(b) 6
(c) 8
(d) 4 (Ans. : d)
Q.2
8051 has ______ user defined software flags. (a) 128
(b) 8
(c) 16
(d) 256 (Ans. : a)
Q.3
8051 has ______ program and external RAM addressability. (a) 16 kBytes
(b) 64 kBytes
(c) 32 kBits
(d) 64 kBits (Ans. : b)
Q.4
8051 has one microsecond instruction cycle with ______ crystal. (a) 12 kHz
(b) 12 mHz
(c) 12 MHz
(d) 12 Hz (Ans. : c)
Q.5
8051 has 32 ______ I/O lines. (a) multidirectional
Q.6
(b) unidirectional
(c) bidirectional
(d) none of these (Ans. : c)
(c) 2
(d) 8
8051 has ______ 8 bit ports. (a) 4
(b) 6
(Ans. : a)
Q.7
8052 has an extra ______ of RAM than the 8051 microcontroller. (a) 128 bits
Q.8
(b) 256 bytes
(c) 512 bits
(d) 128 bytes (Ans. : d)
8052 has an extra ______ of ROM than the 8051 microcontroller. (a) 4K
(b) 2K
(c) 4M
(d) 2M (Ans. : a)
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Q.9
7 - 13
8751 microcontroller has 4K of ______ instead of ROM. (a) EEPROM
Q.10
Microprocessors and Microcontrollers
(b) EPROM
(c) PROM
(d) Both (b) and (c) (Ans. : b)
The CPU of 8051 consists of ______ arithmetic and logic unit. (a) 8 bit
(b) 16 bit
(c) 14 bit
(d) 12 bit (Ans. : a)
Q.11
The CPU of 8051 has ______ PC and DPTR. (a) 16 byte
(b) 16 bit
(c) 8-bit
(d) 24-bit (Ans. : b)
Q.12
8051 has an accumulator of ______ bit. (a) 8
(b) 12
(c) 4
(d) 16 (Ans. : a)
Q.13
Register B of 8051 is a ______ register. (a) flag
Q.14
(b) special function
(c) general purpose
(d) none of these (Ans. : c)
(c) 81 H
(d) 80 H
The internal address of DPH is ______. (a) 83 H
(b) 82 H
(Ans. : a)
Q.15
The internal address of DPL is ______. (a) 83 H
(b) 82 H
(c) 81 H
(d) 80 H (Ans. : b)
Q.16
PSW means ______. (a) Program Standard Word
(b) Program Select Word
(c) Program Status Word
(d) None of the above (Ans. : c)
Q.17
PSW of 8051 is known as ______. (a) general purpose register
(b) serial register
(c) flag register
(d) special function register (Ans. : c)
Q.18
______ flag of 8051 is set if there is an overflow out of bit 7. (a) P
(b) OV
(c) FO
(d) CY (Ans. : d)
Q.19
______ flag also serves as a borrow flag for subtraction. (a) AC
(b) FO
(c) CY
(d) OV (Ans. : c)
Q.20
______ flag is set when there is an overflow out of bit 3. (a) CY
(b) AC
(c) FO
(d) OV (Ans. : b)
Q.21
CY means ______. (a) carry flag
(b) auxiliary carry flag
(c) overflow flag
(d) both (a) and (b) (Ans. : a) TM
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Q.22
7 - 14
Microprocessors and Microcontrollers
AC means ______. (a) carry flag
(b) auxiliary carry flag
(c) overflow flag
(d) both (a) and (b) (Ans. : b)
Q.23
______ select the working register bank. (b) RS1 – RS0
(a) CY
Q.24
Q.25
Q.26
(c) FO
(d) P (Ans. : b)
Bank 0, of register bank is selected when ______. (a) RS1 = RS0 = 0
(b) RS1 = 0, RS0 = 1
(c) RS1 = 1, RS0 = 0
(d) RS1 = RS0 = 1
(Ans. : a)
Bank 1, of register bank, is selected when ______. (a) RS1 = RS0 = 0
(b) RS1 = 1, RS0 = 0
(c) RS1 = 0, RS0 = 1
(d) RS1 = RS0 = 1
When RS1 = 1 and RS0 = 0, ______ of register bank is selected. (a) bank 3 (b) bank 2 (c) bank 1
(Ans. : c) (d) bank 0 (Ans. : b)
Q.27
When RS1 = 1 and RS0 = 1, ______ of register bank is selected. (a) bank 0
(b) bank 1
(c) bank 2
(d) bank 3 (Ans. : d)
Q.28
______ flag is set, when the result of signed number operation is too large which causes high-order bit to overflow into the sign-bit. (a) AC
(b) OV
(c) P
(d) CY (Ans. : b)
Q.29
P flag is defined by number of ones present in the ______. (a) DPH
(b) register b
(c) accumulator
(d) DPL (Ans. : c)
Q.30
P = ___ , if number of 1's are even. (a) 0
(b) 1
(c) cannot be predicted
(d) none of the above (Ans. : a)
Q.31
______ are located immediately above 128 bytes of RAM, in 8051. (a) Special function register.
(b) Flag register
(c) General purpose registers
(d) Accumulator (Ans. : a)
Q.32
Special function registers are between ______ and ______. (a) 00 H and FF H
Q.33
(b) 71 H and F0 H
(c) 80 H and FF H
(d) 00 H and 80 H (Ans. : c)
SFR means ______. (a) Special Function Registers
(b) Special Flag Registers TM
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(c) Standard Function Registers
Microprocessors and Microcontrollers
(d) Standard Flag Registers (Ans. : a)
Q.34
______ are a sort of control table used for running and monitoring the operation of the microcontroller. (a) General Purpose Registers
(b) Flag registers
(c) Special Function Registers
(d) Both (a) and (b) (Ans. : c)
Q.35
Address of accumulator is ______, in 8051. (a) 82 H
(b) 81 H
(c) F0 H
(d) E0 H (Ans. : d)
Q.36
Address of register B is ______, in 8051. (a) E0 H
(b) F0 H
(c) D0 H
(d) 81 H (Ans. : b)
Q.37
Address of PSW is ______, in 8051. (a) E0 H
(b) F0 H
(c) D0 H
(d) 81 H (Ans. : c)
Q.38
Address of stack pointer is ______. (a) E0 H
(b) F0 H
(c) D0 H
(d) 81 H (Ans. : d)
Q.39
Port 0 is located at ______, in 8051. (a) 80 H
(b) 81 H
(c) 82 H
(d) 83 H (Ans. : a)
Q.40
P1 is located at ______, in 8051. (a) 80 H
(b) 90 H
(c) A0 H
(d) B0 H (Ans. : b)
Q.41
P2 is located at ______, in 8051. (a) 80 H
(b) 90 H
(c) A0 H
(d) B0 H (Ans. : c)
Q.42
Port 3 is located at ______, in 8051. (a) 80 H
(b) 90 H
(c) A0 H
(d) B0 H (Ans. : d)
Q.43
IP is located at ______, in 8051. (a) B0H
(b) B8H
(c) A8H
(d) A0H (Ans. : b)
Q.44
IE is located at ______, in 8051. (a) B0 H
(b) B8 H
(c) A8 H
(d) A0 H (Ans. : c)
Q.45
______ is located at 99 H. (a) PCON
(b) TH0
(c) TL0
(d) SBUF (Ans. : d)
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Q.46
7 - 16
Microprocessors and Microcontrollers
______ is located at 87 H. (a) RCAP2L
(b) RCAP2H
(c) PCON
(d) SCON (Ans. : c)
Q.47
Which of the following statement is true for 8051 mC ? (a) 8051 has same data and program memory. (b) 8051 has separate data and program memory. (c) 8051 has only data memory. (d) None of these.
Q.48
(Ans. : b) The unique feature of 8051 is that ___ can manipulate one bit as well as 8 bit data types. (a) SP
(b) PC
(c) ALU
(d) PSW (Ans. : c)
Q.49
Which of the following statement is true for 8051 ? (a) Register B is used for the hardware multiply/divide operation. (b) DPTR is used to perform arithmetic operation. (c) SP is used to hold address of next instruction to be executed. (d) All of the above. (Ans. : a)
Q.50
_____ serves as a base register in indirect jumps, lookup table instructions and external data transfer. (a) SP
Q.51
(c) DPTR
(d) Accumulator (Ans. : c)
____ holds the address of memory location from which the next instruction is to be fetched. (a) SP
Q.52
(b) PC
(b) PC
(c) DPTR
(d) Accumulator (Ans. : b)
(c) F0
(d) RS1
B7 bit of PSW register is _____. (a) CY
(b) AC
(Ans. : a)
Q.53
P is ___ bit of PSW register. (a) B0
Q.54
(b) B1
(c) B2
(d) B3
(c) 0V
(d) P
(Ans. : a)
B2 bit of PSW register is ____. (a) RS1
(b) RS0
(Ans. : c)
Q.55
AC is ____ bit of PSW register. (a) B7
Q.56
(b) B6
(c) B5
(d) B4
(c) AC
(d) CY
(Ans. : b)
B3 bit of PSW register is ___. (a) RS1
(b) RS0
(Ans. : b) TM
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Q.57
7 - 17
F0 is ___ bit of PSW register. (b) B6
(a) B7
Q.58
Microprocessors and Microcontrollers
(c) B5
(d) B4
(c) RS0
(d) RS1
(Ans. : c)
B4 bit of PSW register is ___. (a) AC
(b) F0
(Ans. : d)
Q.59
Bank 0 of 8051 has a range ___. (a) 00 H - 07 H
Q.60
(b) 08 H - 0F H
(d) 18 H - 1F H (Ans. : a)
(c) 10 H - 17 H
(d) 18 H - 1F H (Ans. : b)
(c) bank 2
(d) bank 3
Bank 1 of 8051 has a range ___. (a) 00 H - 07 H
Q.61
(c) 10 H - 17 H
(b) 08 H - 0F H
10 H - 17 H is range for ____. (a) bank 0
(b) bank 1
(Ans. : c)
Q.62
18 H - 1F H is range for ____. (a) bank 0
(b) bank 1
(c) bank 2
(d) bank 3 (Ans. : d)
Q.63
Which statement is false for 8051 ? (a) All 4 ports are bidirectional. (b) All port pins are multiplexed except the pins of port 1. (c) All 4 ports are unidirectional. (d) All of the above.
Q.64
(Ans. : c)
____ can be used as a multiplexed address/data bus. (a) Port 0
(b) Port 1
(c) Port 2
(d) Port 3 (Ans. : a)
Q.65
For proper RST operation ____. (a) reset signal must be low (b) reset signal must be high at least for two machine cycles, while oscillator is running (c) reset signal must be high and then low for one machine cycle (d) none of these (Ans. : b)
Pin Description of 8051 Q.1
8051 is a ______ IC. (a) 40 pin DIP
Q.2
(b) 60 pin DIP
(c) 40 pin SIP
(d) none of these (Ans. : a)
The ______ is used to access data bus of external memory. (a) port 0
(b) port 1
(c) port 2
(d) port 3 (Ans. : a)
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Q.3
7 - 18
Microprocessors and Microcontrollers
______ outputs the lower order byte of the external memory address. (a) Port 0
(b) Port 1
(c) Port 2
(d) Port 3 (Ans. : a)
Q.4
______ outputs the higher order byte of external memory address. (a) Port 0
(b) Port 1
(c) Port 2
(d) Port 3 (Ans. : c)
Q.5
All port pins of ______ are multifunctional. (a) port 0
(b) port 1
(c) port 2
(d) port 3 (Ans. : d)
Q.6
Pin P3.7 is ______. (b) WR
(a) RD
Q.7
(c) T1
(d) T0
(c) P3.5
(d) P3.4
(Ans. : a)
WR is ______. (a) P3.7
(b) P3.6
(Ans. : b)
Q.8
Pin P3.5 is ______. (a) T0
Q.9
(c) RD
(b) T1
(c) RD
(d) WR (Ans. : b)
Pin P3.4 is ______. (a) T0
Q.10
(b) T1
(d) WR (Ans. : a)
INT1 pin number is ______. (a) P3.4
(b) P3.3
(c) P3.2
(d) P3.1 (Ans. : b)
Q.11
INT0 pin number is ______. (a) P3.4
(b) P3.3
(c) P3.2
(d) P3.1 (Ans. : c)
Q.12
Pin P3.1 is ______. (a) INT1
(c) WR
(b) RD
(d) TXD (Ans. : d)
Q.13
Pin P3.0 is ______. (a) RXD
(b) TXD
(c) INT0
(d) INT1 (Ans. : a)
Q.14
For generating internal clock signal, external oscillator is connected to ______. (a) XTAL1, XTAL2
Q.15
(b) Reset
(c) VCC
(d) ALE (Ans. : a)
For proper reset operation, RST must be held high at least for ______ machine cycles, while oscillator is running. (a) 6
(b) 4
(c) 2
(d) 8 (Ans. : c)
Q.16
While reading external memory, PSEN is activated every ______ oscillator periods. (a) 6
(b) 5
(c) 4
(d) 3 (Ans. : a)
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Q.17
7 - 19
Microprocessors and Microcontrollers
______ act as a read strobe to external program memory. (a) ALE
(c) PSEN
(b) EA
(d) RST (Ans. : c)
Q.18
When EA = 1, the address range for internal program memory is ______ through ______. (a) 0000H, 0FFFH
Q.19
(b) 0000H, FFFFH
(d) 1000H, FFFFH (Ans. : a)
When EA = 1, the address range for internal program memory is ______ through ______. (a) 0000H, 0FFFH
Q.20
(c) 1000H, 0FFFH
(b) 0000H, FFFFH
(c) 1000H, 0FFFH
(d) 1000H, FFFFH (Ans. : d)
The alternate use of TXD pin is ____. (a) serial data input
(b) serial data output
(c) parallel data input
(d) parallel data output (Ans. : b)
Q.21
The alternate use of RXD pin is _____. (a) serial data input
(b) parallel data input
(c) serial data output
(d) parallel data output (Ans. : a)
Internal and External Memories Q.1
8051 can access ____ program memory and _____ data memory. (a) 32 K, 32 K
Q.2
(b) 32 K, 64 K
(c) 64 K, 32 K
(d) 64 K, 64 K (Ans. : d)
8051 has _____ of internal program memory and _____ of internal data memory. (a) 4 kbytes, 256 bytes
(b) 8 kbytes, 256 bytes
(c) 4 kbytes, 255 bytes
(d) 8 kbytes, 255 bytes (Ans. : a)
Q.3
In 8051 if RS1 = 0, RS0 = 1 then ______ is selected. (a) bank 0
(b) bank 1
(c) bank 2
(d) bank 3 (Ans. : b)
Q.4
General purpose RAM is above bit addressable area from _____. (a) 20H to 2FH
Q.5
(b) 30H to 37H
(c) 30H to 7FH
(d) 00H to 7FH (Ans. : c)
8051 has internal ROM with address space from ______. (a) 000FH to 00FFH
(b) 0000H to 0FFFH
(c) 1000H to 1FFFH
(d) 0010H to 0FFFH (Ans. : b)
Stack and Stack Pointer Q.1
Stack pointer is _____ wide. (a) 4 bit
(b) 8 bit
(c) 16 bit
(d) 32 bit (Ans. : b)
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Q.2
7 - 20
Microprocessors and Microcontrollers
______ is the area of internal RAM that is used to store and retrieve data immediately. (a) Stack
(b) Stack pointer
(c) Queue
(d) Program counter (Ans. : a)
8051 Timers Q.1
8051 has ____ timers. (a) 2
(b) 4
(c) 6
(d) 8 (Ans. : a)
Q.2
Both T0 and T1 are ___ bit registers. (a) 8
(b) 16
(c) 32
(d) 64 (Ans. : b)
Q.3
When M1 = 0, M0 = 0 timer ____ is selected. (a) mode 0
(b) mode 1
(c) mode 2
(d) mode 3 (Ans. : a)
Q.4
For 8-bits timer (not autoreload) bits (a) 0, 0
M1 M0 = ____.
(b) 0, 1
(c) 1, 0
(d) 1, 1 (Ans. : a)
Q.5
When M1 = 1 and M0 = 0, ____ mode is selected. (a) 8-bit timer
Q.6
(b) 16-bit timer
(c) 8-bit auto-reload
(d) none of these (Ans. : c)
(c) 1, 0
(d) 1, 1
For mode 3, M1 = ____ and M0 = ____. (a) 0, 0
(b) 0, 1
(Ans. : d)
Q.7
If C T = 1, ____ operation is selected. (a) read
(b) write
(c) timer
(d) counter (Ans. : d)
Q.8
Position of TF1 in TCON register is ___. (a) TCON.4
(b) TCON.5
(c) TCON.6
(d) TCON.7 (Ans. : d)
Q.9
In TCON register, TR1 is at ___ position. (a) TCON.4
(b) TCON.5
(c) TCON.6
(d) TCON.7 (Ans. : c)
Q.10
In TCON register, TCON.5 is ___. (a) TF1
(b) TR1
(c) TF0
(d) TR0 (Ans. : c)
Q.11
In TCON register, TCON.4 is ___. (a) TR0
(b) TR1
(c) TF0
(d) TF1 (Ans. : a)
Q.12
IE1 of TCON register is at ___ position. (a) TCON.4
(b) TCON.3
(c) TCON.2
(d) TCON.1 (Ans. : b)
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Q.13
7 - 21
Microprocessors and Microcontrollers
IT1 of TCON register is at ___ position. (a) TCON.3
(b) TCON.2
(c) TCON.1
(d) TCON.0 (Ans. : b)
Q.14
In TCON register, TCON.1 is ___. (a) IE1
(b) IT1
(c) IE0
(d) IT0 (Ans. : c)
Q.15
In TCON register, TCON.0 is ___. (a) IE1
(b) IT1
(c) IE0
(d) IT0 (Ans. : d)
Q.16
Both timers in mode 0 are ___ counters. (a) 8 bit
(b) 12 bit
(c) 16 bit
(d) 32 bit (Ans. : a)
Q.17
Both timers in mode 1 are ____ counters. (a) 8 bit
(b) 12 bit
(c) 16 bit
(d) 32 bit (Ans. : c)
8051 Serial Port Q.1
The serial port of 8051 is ____. (a) half duplex
Q.2
(c) simplex
(d) none of these (Ans. : b)
In 8051, serial port uses register ___ to hold data. (a) SCON
Q.3
(b) full duplex
(b) PCON
(c) SBUF
(d) none of these (Ans. : c)
Serial port of 8051 uses register SCON to ________. (a) control data communication
(b) control data rates
(c) hold data
(d) all of the above (Ans. : a)
Q.4
In 8051, register ____ is used by serial port to control data rates. (a) SCON
Q.5
(b) PCON
(c) SBUF
(d) both (b) and (c) (Ans. : b)
Which of the following statements are true for serial port of 8051 ? i) SBUF is located at 80H. ii) Writing to SBUF loads data to be transmitted. iii) Reading and writing SBUF done in same register. iv) Reading SBUF accesses received data. (a) i), iii)
(b)ii), iv)
(c) all
(d) none (Ans. : b)
Q.6
In 8051, serial data enters and exits through R ´ D in ___. (a) mode 0
(b) mode 1
(c) mode 2
(d) mode 3 (Ans. : a)
Q.7
In mode 0 of 8051's serial port, the baud rate is fixed at ____. TM
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Microprocessors and Microcontrollers
(a)
1 the oscillator frequency 32
(b)
1 the oscillator frequency 12
(c)
1 the clock frequency 8
(d) none of these (Ans. : b)
Q.8
In mode 1 of 8051 serial port, ____ bits are transmitted or received. (a) 8
Q.9
(b) 10
(d) cannot be predicted (Ans. : b)
The baud rate of mode 1 of 8051 serial port is ____. (a) fixed
Q.10
(c) 11
(b) variable
(c) cannot predict
(d) none of these (Ans. : b)
In mode 2 of 8051 serial port, ____ bits are transmitted or received. (a) 8
(b) 10
(c) 11
(d) variable (Ans. : c)
Q.11
The baud rate of mode 2 of 8051 serial port is _____. (a) programmable to
1 the oscillator frequency 32
(b) programmable to
1 the oscillator frequency 64
(c) fixed
(d) either (a) or (b) (Ans. : d)
Q.12
The baud rate of mode 3 of 8051 serial port is _____. (a) fixed (c)
(b) variable
1 the oscillator frequency 12
(d)
1 the oscillator frequency 64 (Ans. : b)
Q.13
In case of 8051 serial port, reception is initiated in mode 0 when ______. (a) RI = 0, REN = 1
Q.14
(b) RI = 1, REN = 0
(c) RI = 1, REN = 1
(d) RI = 0, REN = 0 (Ans. : a)
Using Timer 1 to generate baud rate of 8051 serial port in mode 2, baud rate obtained is _____. K ´ Oscillator frequency K ´ Oscillator frequency (b) (a) 32 ´ 12 ´ [(256 - TH1)] 32 ´ 64 ´ [(256 - TH1)] (c)
K ´ Oscillator frequency 32 ´ 12 ´ [(260 - TH1)]
(d) none of these (Ans. : a)
Q.15
The equation to calculate TH1 for 8051 serial port in mode 1 is _____. K ´ Oscillator frequency 256 ´ Baud rate
(a) TH1 = 256 -
K ´ Oscillator frequency 384 ´ Baud rate
(b) TH1 = 384 -
(c) TH1 = 256 -
K ´ Oscillator frequency Baud rate
(d) none of these (Ans. : a) TM
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Q.16
7 - 23
Microprocessors and Microcontrollers
Which of the following statements are false for 8051 serial port ? i) Value of TH1 must be integer value. ii) PCON is bit addressable iii) The address of PCON is 97 H. iv) When TH1 is FAH, for SMOD = 1, the baud rate = 9600. (a) i), iv)
(b) ii), iii)
(c) i), ii)
(d) iii), iv) (Ans. : b)
Q.17
Q.18
For 8051 serial port mode 1, the baud rate using timer 2 is ___. (a)
Oscillator frequency 32 ´ [65536 - (RCAP2H, RCAP2L)]
(b)
(c)
Osciallator frequency 12 ´ [65536 - (RCAP2H, RCAP2L)]
(d)
Osciallator frequency 64 ´ [65536 + (RCAP2H, RCAP2L)] Osciallator frequency 32 ´ [65536 + (RCAP2H, RCAP2L)] (Ans. : a)
For 8051 serial port in mode 2, when SMOD = 1, baud rate = ___. 1 (a) oscillator frequency (b) oscillator frequency 12 (c)
1 oscillator frequency 32
(d)
1 oscillator frequency 64 (Ans. : c)
Q.19
For 8051 serial port in mode 2, when SMOD = 0, baud rate = _____. (a) oscillator frequency (c)
1 oscillator frequency 32
(b)
1 oscillator frequency 12
(d)
1 oscillator frequency 64 (Ans. : d)
Q.20
For 8051 serial port in mode 2, when SMOD bit is set by _____. (a) ORL PCON, #80H
(b) ORL PCON, #08H
(c) ORL PCON, #10H
(d) ORL PCON, #01H (Ans. : a)
Q.21
Which of the following statements are true for serial port of 8051 ? i) During the transmission of stop bit, 8051 clears the TI flag, i.e. TI = 0. ii) During the reception of stop bit, 8051 sets the RI flag, i.e. RI = 1. iii) Baud rate in 8051 can be doubled by doubling crystal frequency. iv) Baud rate in 8051 can be doubled by making SMOD bit in the PCON register from 0 to 1. (a) ii), iii), iv)
(b) i)
(c) all
(d) none (Ans. : a)
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8051 Interrupt Structure Q.1
In ______ method, the microcontroller's program checks each of the I/O devices to see if any device needs service and if so, provides the required service. (a) polling
(b) interrupt
(c)calling
(d) jump (Ans. : a)
Q.2
In ______ method, the device that needs service, from microcontroller, sends an interrupt signal to the microcontroller. (a) polling
(b) interrupt
(c) calling
(d) jump (Ans. : b)
Q.3
An interrupt caused by an ______ signal is referred as a hardware interrupt. (a) external
Q.4
(b) internal
(c) both (a) and (b)
(d) vector interrupts (Ans. : a)
Conditional interrupts or interrupts caused by special instructions are called ______. (a) software interrupts
(b) hardware interrupts
(c) both (a) and (b)
(d) maskable interrupts (Ans. : a)
Q.5
______ interrupts are enabled and disabled under program control. (a) Maskable
Q.6
(b) Non-maskable
(b) does not respond (c) resets
(d) None of these (Ans. : b)
Interrupts that cannot be masked under software control are called ______ interrupts. (a) maskable
Q.8
(d) Non-vectored (Ans. : a)
When masked, processor ______ to activated interrupt. (a) responds
Q.7
(c) Vectored
(b) non-maskable
(c) vectored
(d) non-vectored (Ans. : b)
The interrupt for which starting address of the ISR is predefined is called ______. (a) vectored interrupts
(b) non-vectored interrupts
(c) maskable interrupt
(d) none of the above (Ans. : a)
Q.9
Response time for vectored interrupts is ______ than non-vectored interrupts. (a) more
Q.10
(d) does not matter (Ans. : c)
(b) Non-vectored
(c) Maskable
(d) None of these (Ans. : b)
When 8051 is reset, the status of interrupts is ______. (a) enabled
Q.12
(c) less
______ interrupt do not have a predefined starting address. (a) Vectored
Q.11
(b) same
(b) disabled
(c) cannot predict
(d) none of these (Ans. : b)
(c) IE.6
(d) IE.7
Bit position of EA is ______. (a) IE.4
(b) IE.5
(Ans. : d) TM
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Q.13
7 - 25
Microprocessors and Microcontrollers
IE.5 is ______. (a) EA
(b) ET2
(c) ES
(d) ET1 (Ans. : b)
Q.14
Bit position of ES is ______. (a) IE.1
(b) IE.2
(c) IE.3
(d) IE.4 (Ans. : d)
Q.15
IE.3 is ______. (a) EA
(b) ES
(c) ET1
(d) ET2 (Ans. : c)
Q.16
IE.2 is ______. (a) EX0
(b) EX1
(c) EX2
(d) ET1 (Ans. : b)
Q.17
Bit position of ET0 is ______. (a) IE.0
(b) IE.1
(c) IE.2
(d) IE.3 (Ans. : b)
Q.18
Bit position of EX0 is ______. (a) IE.0
(b) IE.1
(c) IE.2
(d) IE.3 (Ans. : a)
Q.19
______ SFR is used to enable and disable the interrupt. (a) IP
(b) IE
(c) P3
(d) PSW (Ans. : b)
Q.20
By setting or clearing bits in ____, the priority of any interrupt can be decided. (a) IP
(b) IE
(c) P3
(d) PSW (Ans. : a)
Q.21
____ are reserved bits of IP register. (a) IP.7, IP.6, IP.5
Q.22
(c) IP.5, IP.4, IP.3
(d) IP.6, IP.5, IP.4 (Ans. : a)
(b) PT1
(c) PX1
(d) PT0
IP.4 is ____. (a) PS
Q.23
(b) IP.7, IP.4, IP.3
(Ans. : a)
Bit position of PT1 in IP is ____. (a) IP.6
(b) IP.4
(c) IP.3
(d) IP.1 (Ans. : c)
Q.24
Bit position of PX1 is ____. (a) IP.4
(b) IP.3
(c) IP.2
(d) IP.1 (Ans. : c)
Q.25
IP.1 is ___. (a) PT1
(b) PX1
(c) PT0
(d) PX0 (Ans. : c)
Q.26
IP.0 is ___. (a) PT1
(b) PX1
(c) PT0
(d) PX0 (Ans. : d)
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Q.27
7 - 26
Microprocessors and Microcontrollers
Vector location of INT0 is ____. (a) 0003H
(b) 000BH
(c) 0013H
(d) 001BH (Ans. : a)
Q.28
000B H is vector location of ___. (a) INT0
(b) TF0
(c) INT1
(d) TF1 (Ans. : b)
Q.29
Vector location of TF1 is ____. (a) 000BH
(b) 0013H
(c) 001BH
(d) 0023H (Ans. : c)
Q.30
0013H is vector location of ___. (a) TF0
(b) INT0
(c) TF1
(d) INT1 (Ans. : d)
Q.31
Vector location of RI and TI is ____. (a) 0013H
(b) 001BH
(c) 0023H
(d) 002BH (Ans. : c)
Q.32
INT0 has ___ priority. (a) highest
Q.33
(b) lowest
(d) cannot be predicted (Ans. : a)
(b) lowest
(c) medium
(d) cannot be predicted (Ans. : b)
(b) INT1
(c) TF0
(d) TF1
RI and TI has ____ priority. (a) highest
Q.34
(c) medium
Pin P3.2 is ____. (a) INT0
(Ans. : a)
Q.35
The method in which microcontroller's program simply checks each of the I/O devices to see if any device needs servicing is called ____. (a) Pipelining
(b) Polling method
(c) Interrupt method
(d) Round Robin method (Ans. : b)
Q.36
With help of _____, the interrupt transfers the program control to ISR. (a) interrupt service routine
(b) interrupt vector table
(c) accumulator
(d) none of these (Ans. : b)
Q.37
Interrupt caused by an external signal is referred as _____. (a) software interrupt
(b) hardware interrupt
(c) non-maskable interrupt
(d) none of these (Ans. : b)
Q.38
When _____ of interrupt is done, processor does not respond to the interrupt even though the interrupt is activated. (a) masking
(b) unmasking
(c) either (a) or (b)
(d) none of these (Ans. : a)
qqq TM
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8
Transducers
Chapter at a Glance Important Definitions 1. Transducer : A transducer is a device which converts a physical quality such as temperature, pressure, displacement, force, etc., into equivalent electrical signal either voltage or current. 2. Active Transducers : Active transducers are self generating type of transducers. These transducers develop an electrical parameter (i.e. voltage/current) which is proportional to the quantity under measurement. These transducers do not require any external source or power for their operation. 3. Passive Transducers : Passive transducers do not generate any electrical signal by themselves. To obtain an electrical signal from such transducers, an external source of power is essential. Passive transducers depend upon the change in an electrical parameter (R, L or C). They are also known as externally power driven transducers. 4. Primary Transducer : A transducer which converts physical quantity into mechanical signal is called primary transducer. 5. Secondary Transducer : A transducer which converts mechanical signal into an electrical signal is called secondary transducer. 6. Electrical Transducer : A transducer which gives output in electrical form it is known as electrical transducer. 7. Sensor : Sensor is a device that produces a measurable response to a change in a physical condition, such as temperature or thermal conductivity, or to a change in a chemical concentration. 8. RTD : Electrical resistance of any metallic conductor varies according to temperature changes. The primary electrical transducer which measures the temperature using this phenomenon is called Resistance Temperature Detector (RTD) or Resistance Thermometer. 9. Thermistor : Thermistors are semiconductor device which behave as thermal resistors having negative temperature coefficient [NTC]; i.e. their resistance decreases as temperature increases. (8 - 1) TM
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10. LVDT : LVDT (Linear Variable Differential Transducer) is a variable inductance displacement transducer in which the inductance is varied according to the displacement. 11. Photoelectric Effect : When the ray of light is incident on metal surface, the quantum energy of electron is converted to kinetic energy causing the electrons to move and thus resulting into flow of current in the metal. This phenomenon is known as photoelectric effect.
Important Questions and Answers
Ø
Draw the block diagram of instrumentation system and state the function of each block.
· Instrumentation plays an important role in industrial automation. The Fig 8.1 shows the block diagram of a instrumentation system. It indicates the necessary elements and their functions in a general measuring system. Recorder
Measurand
Transducer
Data transmission element
Signal conditioning elements
Data presentation element
Printer Display Controller
Fig. 8.1 Block diagram of an instrumentation system
· The functional elements in the block diagram can be grouped as 1. Transducer 2. Signal conditioning elements 3. Data presentation element
· Each element is made up of number of distinct components which perform a particular function in the measurement procedure. Measurand : Most of the times input to the instrumentation system is the physical quantity such as temperature, pressure, displacement, force, etc. Such non-electrical input quantity is called measurand. Transducer : A transducer converts the non-electrical proportional electrical signal such as voltage or current.
input
measurand
into
a
Signal Conditioning Element : The signal conditioning element processes the output of the transducer and makes it suitable for control, recording and display. The signal conditioning element performs one or more of the following functions : 1. Amplification of input signal
2. Analog to digital conversion
3. Filtering to remove noise
4. Modulation TM
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Data Transmission Element : The data transmission element provides the transmission path required for sending the signal from signal conditioning element to the other stages of the instrumentation system. The examples of data transmission elements are : 1. Electrical cables/wires
2. Fiber optics cables
3. Radio links
Data Presentation Element : The transmitted data may be used for monitoring, controlling or analysing purposes. So to get the information in proper form, according to the purpose for which it is intended for, the data presentation element does the following functions : 1. Amplification/attenuation
2. Demodulation 3. A/D or D/A conversion
4. Data conversion to make it suitable for controlling printing and display. Controller, Recorder, Printer and Display Units : Controllers are used to make the corrective action and control certain parameters. On the other hand, recorder, printer and display units are used to monitor the variations in the certain parameters.
Ø
Compare active and passive transducers.
Sr. No.
Active Transducers
Passive Transducers
1.
They do not require any external source or power for their operation.
They require an external source of power for their operation.
2.
They are self generating type transducers.
They are not self generating type transducers.
3.
They produce electrical parameter such as voltage or current proportional to the physical parameter under measurement.
They produce parameter such capacitance in parameter under
4.
Examples : Thermocouple, piezoelectric transducers.
Examples : Thermistor, RTD, LDR, LVDT, phototransistor.
Ø
photocell,
change in the electrical as inductance, resistance or response to the physical measurement.
With neat diagram compare primary and secondary transducer.
Sr. No.
Primary Transducer
Secondary Transducer
1.
A transducer which converts physical quantity into mechanical signal is called primary transducer.
A transducer which converts mechanical signal into an electrical signal is called secondary transducer.
2.
They do not require any electrical power for their operation.
They require electrical power for their operation.
Table 8.1 TM
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Ø
8-4
Transducers
What is electrical transducer ?
· A transducer which gives output in electrical form it is known as electrical transducer. · Actually, electrical transducer consists of two parts which are very closely related to each other. These two parts are sensing or detecting element and transduction element. The sensing or detecting element is commonly known as sensor. · Definition states that sensor is a device that produces a measurable response to a change in a physical condition, such as temperature or thermal conductivity, or to a change in a chemical concentration. · The transduction element transforms the output of the sensor to an electrical output, as shown in the Fig. 8.2. Non-electrical quantity
Sensing element
Sensor response
Transduction element
Electrical signal
Fig. 8.2 Electrical Transducer
Ø
Explain the principle used in the resistive transducer.
· In general, the resistance of a metal conductor is given by, rL R = A where r = Resistivity of conductor (W m) L = Length of conductor (m) A = Area of cross-section of conductor (m 2 )
· The electrical resistive transducers are designed on the basis of the methods of variation of any one of the quantities in above equation; such as change in length, change in area of cross-section and change in resistivity. · The resistance change due to the change in the length of the conductor is used in translational or rotational potentiometers to measure linear or rotational displacement. The change in resistance of conductor or semiconductor due to the strain applied is the working principle of the strain gauge which is used to measure various physical quantities such as pressure, displacement and force. The change in resistivity of conductor due to the temperature variations causes change in resistance. This principle is used to measure temperature.
Ø
Explain the principle of operation of RTD.
· The resistance of a conductor changes when its temperature changes. This property is used for the measurement of temperature. The resistance thermometer determines the change in the electrical resistance of the conductor to determine the temperature. TM
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Transducers
· The relationship between temperature and resistance of conductor is given by equation : Rt = Rref [ 1 + a D t ] Where Rt
: Resistance of the conductor at temperature t ºC,
Rref : Resistance of the conductor at the reference temperature, usually 0 ºC, a
: Temperature coefficient of the resistance,
D t : Difference between the temperature to be measured and reference temperature.
· Almost all metallic conductors have a positive temperature coefficient so that their resistance increases with an increase in temperature. · A high value of a is desirable in a temperature sensing element so that a substantial change in resistance occurs for a relatively small change in temperature. · This change in resistance [D R] can be measured with a Wheatstone bridge, the output of which can be directly calibrated to indicate the temperature which caused the change is resistance. · At 0 ºC, the resistance of RTD is usually 100 W. By choosing R3 = 100 W and R1= R2, the bridge is balanced at 0 ºC. Therefore, at 0 ºC voltage across B and D is zero and hence the output voltage is zero. · Any change in the RTD resistance due to change in temperature unbalances the bridge circuit resulting voltage across B and D terminal. This voltage is proportional to the change in the resistance and hence to the change in the temperature.
Amp
Output
A R2
R1 VCC
+
B
D
–
RTD
R3 C
Fig. 8.3 RTD resistance measurement
Ø
State the advantages of RTD.
1. High accuracy. 2. They can be calibrated to detect the actual temperatures to within ± 0.25 ºC up to 120 ºC and ± 0.5 ºC from 120 ºC to 550 ºC. Therefore they have wide temperature range. TM
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Transducers
3. Does not require temperature compensation.
4. Designed for fast response.
5. Excellent stability.
6. Good sensitivity.
7. High reproducibility.
Ø
State the disadvantages of RTD.
1. Requires bridge circuit and external power source for measurement. 2. Chances of self heating due to current through RTD and thus the change in resistance. 3. Large size as compared to thermocouples. 4. High cost.
Ø
Compare types of temperature transducers or compare RTD with thermistors.
Parameter Principle of operation
Resistance Thermometer
Thermistor
Resistance increases with increase in Resistance decreases with increase in temperature temperature.
Temperature coefficient
Positive
Negative
Characteristic
Linear
Nonlinear
Sensitivity
Medium
High
Speed of Response
High
High over narrow temperature range
Operating temperature range
– 200 ° C to + 650 ° C
– 100 ° C to + 200 ° C
Type of transducer
Passive
Passive
Accuracy
High
Moderate
Size
Large
Small
Cost
High
Low
Material used
Nickel, Copper, Platinum etc.
Compensation Applications
Ø
Manganese, Nickel, Cobalt, Copper, iron and uranium
Not required Suitable for applications where speed of response and accuracy are more important.
Not required Suitable for applications where required temperature range is small and sensitivity requirement is high.
State the advantages of LVDT.
A) Mechanical 1. Wide range of displacement : ± 0.005 to ± 25 inch. 2. Frictionless operation : No physical contact exists between the core and coil structure. TM
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3. Ruggedness : Good mechanical life. 4. Insensitive to temperature changes. 5. Highly repeatable response (performance). B) Electrical 1. Linearity : Better (Output voltage is a linear function of mechanical displacement). 2. High sensitivity. 3. Resolution : Infinite. 4. Electrical isolation is better.
Ø
State the disadvantages of LVDT.
1. Comparatively large displacements are necessary for appreciable differential output. 2. They are sensitive to stray magnetic fields. However, this interference can be reduced by shielding. 3. The dynamic response is limited by the mass of the core. 4. Temperature affects the transducer.
Ø
State the applications of LVDT.
1. The LVDT can be used in all applications where displacement ranging from fractions of a few mm to a few cm have to be measured. 2. Acting as a secondary transducer, LVDT can be used as a device to measure force, weight, and pressure etc. The force or pressure to be measured is first converted into a displacement using primary transducers. Then this displacement is applied to an LVDT, that acts as a secondary transducer, and converts the displacement into proportional output voltage. In these applications the high sensitivity of LVDT is a major attraction.
Ø
Write a note on piezoelectric transducers.
The construction of the piezoelectric transducer is as shown in the Fig. 8.4. Pressure
Force summing member
Crystal
Vo
Base
Fig. 8.4 Piezoelectric transducer TM
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Transducers
A crystal is placed between solid base and force summing member. Metal electrodes plated on to faces of piezoelectric crystal are taken out to measure output. The electrodes become plates of the parallel plate capacitor. Thus it can be considered as charge generator. The output voltage is given by Q Vo = C
Ø
Write a note on photoelectric transducers.
· The principle of photoelectric transducers is the physical radiation on matter. · When the ray of light is incident on metal surface, the quantum energy of electron is converted to kinetic energy causing the electrons to move and thus resulting into flow of current in the metal. This phenomenon is known as photoelectric effect. Photoelectric effects
Photoemissive
Photoconductive (resistive)
Photovoltaic
Fig. 8.5
· Photo-emissive Transducer consist of a metallic cathode and an anode in an evacuated tube. The electrons emitted by the cathode are attracted by the anode, causing the current to flow which is proportional to the amount of light incident on the metal surface. The optical radiation affects either the current developed voltage or resistance. · Photovoltaic cells are self generating and are favoured for use in exposure meters. · In photoresistive cells the resistance value change according to the illumination of light. Photoresistive cells, are passive in nature. Photoresistive cell is also known as Light Dependent Resistor (LDR). · Photodiodes and photo transistors work in both photoemissive and photovoltaic modes.
Multiple Choice Questions with Answers Introduction Q.1
_____ converts the non-electrical input measurand into a proportional electrical signal. (a) Data presentation element
(b) Data transmission element
(c) Signal conditioning elements
(d) Transducer (Ans. : d)
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Transducers
Transducers Q.1
Which of the following transducers are self generating type of transducers ? (a) Active transducers
(b) Passive transducers
(c) both (a) and (b)
(d) none of these (Ans. : a)
Resistive Transducers Q.1
R = _______. (a)
rA L
(b)
A L
(c)
rL A
(d) rLA (Ans. : c)
Q.2
The working principle of _____ is, the change in resistance of conductor or semiconductor due to the strain applied. (a) Temperature transducer
(b) Strain gauge
(c) RTD
(d) Thermocouple (Ans. : b)
Q.3
In _____, resistance of metallic conductor varies according to temperature changes. (a) LVDT
(b) strain guage
(c) piezoelectric transducer
(d) resistance thermometer (Ans. : d)
Q.4
For RTD, Rt = _______. (b) Rref [1 + a D t ]
(a) Rref [ a D t ]
(c) Rref [1 – a D t ]
(d)
Rref 1+ aDt (Ans. : b)
Q.5
At 0°C what is the value of RTD ? (a) 1 k W
(b) 10 k W
(c) 100 W
(d) 100 k W (Ans. : c)
Q.6
Which of the following statements are true for RTD ? (a) RTD has low accuracy
(b) RTD has excellent stability
(c) RTD requires temperature compensation
(d) None of these (Ans. : b)
Q.7
RTD cost is ______. (a) high
(b) low
(c) moderate
(d) varying (Ans. : a)
Thermistors Q.1
Thermistors have _____ temperature coefficient. (a) negative
(b) positive
(c) variable
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(d) none of these (Ans. : a)
Basic Electronics
Q.2
8 - 10
Transducers
Which of the following are advantages fo thermistor ? (i) Low cost
(ii) Not suitable for wide temperature range
(iii) For narrow temperature range, response is fast (iv) Small size (v) Requires Wheatstone bridge for measurement. (a) (i), (iii), (iv)
Q.3
(b) (ii), (iv)
(c) (i), (ii), (iii), (iv) (v) (d) none of the above (Ans. : a)
Thermistor is used as ________. (a) Strain gauge
(b) Pressure transducer
(c) temperature transducer
(d) none of these (Ans. : c)
Comparison between Resistance Thermometer and Thermistor Q.1
The operating temperature of resistance thermometer ranges from _____. (a) – 300 ° C to + 600 ° C
(b) – 200 ° C to + 600 ° C
(c) – 200 ° C to + 650 ° C
(d) – 100 ° C to + 500 ° C (Ans. : c)
Linear Variable Differential Transducer (LVDT) Q.1
LVDT stands for ______. (a) Linear variable differential transducer
(b) Linear variable derivational transducer
(c) Linear variable division transducer
(d) none of these (Ans. : a)
Q.2
The core of LVDT is made up of _______. (a) zinc alloy
(b) nickel-iron alloy
(c) aluminum
(d) copper (Ans. : b)
Active Electrical Transducers Q.1
________ transducer consist of a metallic cathode and an anode in an evacuated tube. (a) Photo-emissive
(b) LVDT
(c) Resistance thermometer
(d) Thermistor (Ans. : a)
Q.2
LDR means _______. (a) Liquid display resistor
(b) Linear differential resistor
(c) Light dependent resistor
(d) Linear display resistor (Ans. : c)
qqq
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Chapter at a Glance Important Definitions 1. Baseband Signal : Regardless of whether the original information signals are analog or digital, they are all referred to as “baseband signals”. 2. Baseband Transmission : In a communication system, the original information signals (baseband signals) may be transmitted over the medium. Putting the original signal directly into the medium is referred to as “baseband transmission”. 3. Modulation : The process by which the baseband signal modifies the carrier signal is called modulation. 4. Amplitude Modulation : Amplitude Modulation (AM) is defined as system of modulation in which the instantaneous value of the carrier amplitude changes in accordance with the amplitude of the modulating signal. 5. Modulation Index : Relationship between the amplitudes of the modulating and carrier signals is important and it is expressed in terms of their ratio, commonly known as modulation index (m). It is also called modulation factor, modulation coefficient or the degree of modulation. 6. Percentage Modulation : The modulation index is a number lying between 0 and 1, and it is very often expressed as a percentage and called the percentage modulation. 7. Overmodulation in AM : In AM wave overmodulation takes place when modulation index exceeds 1, i.e. when Vm > Vc . In overmodulated AM wave for some part of time, amplitude of wave is zero and during this time, the amplitude of the carrier signal is not proportional to the amplitude of modulating signal. This results loss of information in the AM wave and hence the overmodulation must be avoided. 8. Detector : The detector, also called the demodulator, is the part of the receiver that recovers the baseband signal or original modulating signal. It performs the inverse operation to the transmitter modulator. 9. Frequency Modulation : When frequency of the carrier varies as per amplitude variations of modulating signal, then it is called Frequency Modulation (FM). Amplitude of the modulated carrier remains constant. (9 - 1) TM
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10. Frequency Deviation : The amount of change in carrier frequency produced by the modulating signal is known as frequency deviation. 11. Modulation index for FM : The modulation index is the ratio of the frequency deviation to the modulating frequency. Frequency deviation m f = Modulation index = Modulating frequency
Important Formulae 1.
l =
c f
... wavelength
2. Modulation index for AM m =
Vm V - Vmin = max Vc Vmax + Vmin
3. Expression for AM wave v m = Vm sinwm t 4. Frequency Spectrum of AM wave fUSB = fc + fm fLSB = fc - fm mVc mVc v AM = Vc sin wc t + cos ( wc - wm ) t cos (wc + wm ) t 14243 2 144424443 1244424443 carrier Lower side band Upper side band
… (9.1)
mVc mVc v AM = Vc cos wc t + cos ( wc - wm ) t + cos (wc + wm ) t 14243 1244424443 1244424443 carrier Lower side band Upper side band
… (9.1 (a))
5. Bandwidth of AM wave BW = 2fm 6. Carrier power of AM wave Pc =
Vc2 2R
7. Power in sideband of AM wave PLSB = PUSB =
m 2 Vc2 m2 = P 8R 4 c
8. Total power in AM wave æ m2 Ptotal = Pc ç 1 + ç 2 è
ö ÷ ÷ ø TM
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9. Modulation index of AM wave interms of Ptotal and Pc m =
æP ö 2 ç total - 1 ÷ P è c ø
10. Transmission efficiency of AM wave h =
m2 2 + m2
11. Percentage transmission efficiency of AM wave %h =
m2 2 + m2
´ 100 %
12. Total power of AM in case of simultaneous modulation æ m2 Ptotal = Pc ç 1 + t 2 ç è
ö ÷ ÷ ø
13. Total modulation index of AM in case of simultaneous modulation mt =
m 21 + m 22 +.....+ m 2n
14. Bandwidth of AM with several modulation signals BW = 2fmax 15. For practical diode detector Mmax =
R 1 series with (R 2||R 3||R 4 ) R1 + R2
16. Expression for FM Df v = A sin éêwc t + sin wm t ùú f m ë û = A sin [wc t + m f sin wm t ] 17. Modulation index for FM mf =
Df d = fm fm
18. Bandwidth for FM BWFM = 2[Df + fm ] 19. Expression for PM wave v = A sin [wc t + m p sinwm t]
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Important Questions and Answers
Ø
Explain the elements of communication system with the help of block diagram.
· Any electronic communication system can be represented in its basic form, as shown in the Fig. 9.1. Information source
Transmitter
Communication channel or medium
Receiver
Destination
Noise source
Fig. 9.1 Block diagram of communication system
The basic components of communication systems are transmitter, a communication channel or medium, and a receiver. Noise is inherently present in the channel or medium. It gets added to the information being communicated. The elements of communication system are as follows : Information n n
Transmitter
n
Communication channel or medium
n
Noise
n
Receiver
Information
· The communication systems communicate messages. The message comes from the information sources. The two main sources of information are the ideas emanating from the human brain and changes in any physical environment. It may contain human voice, picture, code, data, music and their combinations. · To have a better communication system, selective, but all information must be communicated with no redundancy since we know no real information can be conveyed by a redundant message. Transmitter
· The transmitter is a collection of electronic circuits designed to convert the information into a signal suitable for transmission over a given communication medium. · Most of the times message that comes from information source is non-electrical and therefore it is not suitable for immediate transmission. · Such messages need to be coded or processed before transmission and also require suitable transducers to convert them into electrical signals. The built-in circuitry such as TM
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decoders, encoders, transducers, etc. in the transmission makes incoming information suitable for transmission and subsequent reception.
· The most of the transmitters have built-in amplifier circuits. These circuits amplify the incoming signals (information) before transmission which help in faithful reception of the transmitted information at the receiver end. Communication channel
· The communication channel is the medium by which the electronic signal is transmitted from one place to another. The communication medium can be a pair of conducting wire, coaxial cable, optical fibre cable or free space. Noise
· Noise is random, undesirable electric energy that enters the communication system via the medium and interferes with the transmitted message. Some noise is also produced in the receiver. · Noise can be either natural or man-made. Natural noise includes noise produced in nature, e.g. from lighting during rainy season, or noise due to radiations produced by the sun and the other stars. · Man-made noise is the noise produced by electric ignition systems of cars, electric motors, fluorescent lights, etc. · Noise is one of the serious problems of electronic communication. It cannot be completely eliminated. However, there are ways to deal with noise, and reduce the possibility of degradation of signal due to noise. Receiver
· A receiver is a collection of electronic circuits designed to convert the signal back to the original information. It consists of amplifier, detector, mixer, oscillator, transducer and so on.
Ø
Explain the need for modulation.
+
VTU : Feb.-2000, 09, Aug.-01, 02, 04, 05, 08, Jan.-11
· We have seen that baseband signals are incompatible for direct transmission over the medium and therefore we have to use modulation technique for the communication of baseband signal. The advantages of using modulation technique are as given below : n
Reduces the height of antenna
n
Avoids mixing of signals
n
Increases the range of communication
n
Allows multiplexing of signals
n
Allows adjustments in the bandwidth
n
Improves quality of reception. TM
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1. Reduces the height of antenna
· The height of the antenna required for transmission and reception of radio waves in radio transmission is a function of wavelength of the frequency used. The minimum height of the antenna is given as l/4. The wavelength l is given as, l = where
c f
c is the velocity of light and f is the frequency.
· From the above equation it can be easily noticed that at low frequencies wavelength is very high and hence the antenna height. For example, consider the baseband signal with f = 15 kHz. Then · Height of antenna =
l c 3 ´ 10 8 = = = 5000 meters 4 f ´ 4 15 ´ 10 3 ´ 4
· This 5000 meters height of a vertical antenna is unthinkable and unpractical. On the other hand, if we consider a modulated signal with 1 MHz frequency in the broadcast band the height of antenna is given as, · Height of antenna =
l c 3 ´ 10 8 = = = 75 meters 4 f ´ 4 1 ´ 10 6 ´ 4
· This height of antenna is practical and such antenna can be installed. 2. Avoids mixing of signals
· All sound signals are concentrated within the range from 20 Hz to 20 kHz. The transmission of baseband signals from various sources causes the mixing of signal and then it is difficult to separate at the receiver end.
Signal 1 0 Signal 2 0 Signal 3 0
Frequency 20 kHz
Signal 1 Modulated with carrier of 100 kHz
Signal 2 Modulated with carrier of 200 kHz
Signal 3 Modulated with carrier of 300 kHz
Frequency 20 kHz Frequency 20 kHz
Frequency 80 kHz
120 kHz
Channel 1 bandwidth
180 kHz
220 kHz 280 kHz
Channel 2 bandwidth
Fig. 9.2 Modulation avoids mixing of signals
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320 kHz
Channel 3 bandwidth
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· In order to separate the various signals, it is necessary to translate them all to different portions of the electromagnetic spectrum (channel); each must be given its own bandwidth commonly known as channel bandwidth. This can be achieved by taking different carrier frequency for different signal source as shown in the Fig. 9.2. Once the signals have been transmitted, a tuned circuit at the receiver end selects the portion of the electromagnetic spectrum it is tuned for. Therefore modulating different signal sources by different carrier frequencies avoid mixing of signals. 3. Increases the range of communication
· At low frequencies radiation is poor and signal gets highly attenuated. Therefore baseband signals cannot be transmitted directly over long distance. Modulation effectively increases the frequency of the signal to be radiated and thus increases the distance over which signals can be transmitted faithfully. 4. Allows multiplexing of signals · The modulation permits multiplexing to be used. Multiplexing means transmission of two or more signals simultaneously over the same channel. The common examples of multiplexing are the number of Television channels operating simultaneously or number of radio stations broadcasting the signal in MW and SW band, simultaneously.
· The different signals from different stations can be separated in the receiver since the carrier frequencies for these signals are different. It is commonly known as tuning the receiver to the desired station. By tuning process, the desired signal is selected and at the same time, other unwanted signals are rejected. 5. Allows adjustments in the bandwidth
· Bandwidth of a modulated signal may be made smaller or larger than the original signal. Signal to noise ratio in the receiver which is a function of the signal bandwidth can thus be improved by proper control of the bandwidth at the modulating stage. 6. Improves quality of reception
· The signal communication using modulation techniques such as frequency modulation, pulse code modulation reduce the effect of noise to great extent. Reduction in noise improves the quality of reception.
Ø Ø
+ +
Derive the expression for AM wave. Write the expression for AM wave
VTU : Aug.-04, 06, Feb.-10 VTU : Feb.-99, 03, Marks 2
The instantaneous values of modulating signal and carrier signal can be represented as given below. Instantaneous value of modulating signal where
v m = Vm sin wm t v m = Instantaneous amplitude Vm = Maximum amplitude wm = 2p fm = Angular frequency and TM
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fm = Frequency of modulating signal Instantaneous value of carrier signal vc = where
Vc sin wc t
v c = Instantaneous amplitude Vc = Maximum amplitude wc = 2p fc = Angular frequency and fc = Frequency of carrier signal
Instantaneous value of amplitude modulated signal Using above given mathematical expressions for modulating and carrier signals, we can create a new mathematical expression for the complete modulated wave, as given below VAM = Vc + v m Q v m = Vm sin wm t
= Vc + Vm sin wm t \
The instantaneous value of the amplitude modulated wave can be given as v AM = VAM sin q = VAM sin wc t = (v c + Vm sin wm t) sin wc t
Ø Ø
Derive an expression for modulation index in AM.
+
VTU : Aug.-2000, 02, Marks 4
Define modulation for AM.
· Looking at Fig. 9.3 we can visualize that something unusual (distortion) will occur if Vm is greater than Vc. Therefore, the modulating signal voltage Vm must be less than the carrier voltage Vc for proper amplitude modulation. This relationship between the amplitudes of the modulating and carrier signals is important and it is expressed in terms of their ratio, commonly known as modulation index (m). It is also called modulation factor, modulation coefficient or the degree of modulation. The m is the ratio of the modulating signal voltage to the carrier voltage : m=
Vm Vc
· The modulation index is a number lying between 0 and 1, and it is very often expressed as a percentage and called the percentage modulation.
Ø
Define modulation index in terms of Vmax and Vmin.
+
VTU : May-10, Marks 5
· Fig. 9.3 shows the amplitude modulated wave in time domain. Here, horizontal axis represents time, and the vertical axis represents the amplitude of the signals. Looking at Fig. 9.3 we can write, Vmax – Vmin K (9.1) Vm = 2 TM
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+
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Vc Vm
(Vc+Vmsin wmt) Vmin V
Vm
Vmax
t
0
–(Vc+Vmsin wmt) –
Fig. 9.3 Amplitude modulated wave
and Vc = Vmax – Vm By substituting value of Vm in equation – Vmin æV = Vmax – ç max 2 è =
K (9.2) (9.2) we get, ö ÷ ø
2 Vmax – Vmax + Vmin 2
Vmax + Vmin 2 Now dividing equation (9.1) by equation (9.3), (V – Vmin ) / 2 V We have, m = m = max (Vmax + Vmin ) / 2 Vc Vc =
\
m = m =
K (9.3)
Vm Vc Vmax – Vmin Vmax + Vmin
K (9.4)
· The equation (9.4) gives the standard method for calculating modulation index from the amplitude modulated waveform which may be displayed on the screen of the oscilloscope.
Ø
Explain the working of envelope detector.
· The simplest, and most popular, demodulator for full-carrier AM is the envelope detector. This form of demodulator takes advantage of the simplicity of the AM signal. TM
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All that is necessary to recover the baseband signal is to rectify the incoming signal to remove half of the envelope, and then use a low-pass filter to remove the high-frequency components of the signal.
· The Fig. 9.4 shows the envelope detector circuit. It consists of diode as a half wave rectifier and RC circuit as a low pass filter. This circuit is also known as diode detector. · As shown in the Fig. 9.4 the AM D signal is transformer coupled and applied to a basic half wave rectifier Vo AM circuit consisting of D and R. In the signal C R Demodulated positive half cycle of the AM signal output diode conducts and current flows through R whereas in the negative half cycle diode is reverse biased Fig. 9.4 Diode detector and no current flows through R. As a result only positive half of the AM wave appears across resistor R as shown in the Fig. 9.5 (b). The capacitor connected in parallel with resistance R provides very low impedance at the carrier frequency and a much higher impedance at the modulating frequency. As a result capacitor effectively shorts or filters out the carrier, thereby leaving the original modulating signal. (See Fig. 9.5 on next page.)
Ø
Explain the working of practical diode detector.
· Number of additions have been done in the simple diode circuit to improve the performance. Fig. 9.6 shows the practical envelope detector circuit. IF in
AGC out R3
R1
C
C1
C3 C2
R2 R4
AF out
Fig. 9.6 Practical diode detector
· Here, diode is connected reverse and due to reverse connection negative envelope is demodulated instead of positive. This has no effect on detection, but it gives negative AGC voltage. The resistor R of the simple diode detector is split into two parts (R1 and R 2 ). R1 and C1 forms a low pass filter and R 2 provides series d.c. path to ground for the diode. Capacitor C2 acts as a coupling capacitor and prevents the diode dc output from TM
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V
t
0
(a) AM signal
V
t
0
(b) Current pulses through diode D
V
t
0 (c) Demodulating signal
Fig. 9.5 Demodulator waveforms TM
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reaching the volume control R 4 . The R 3 and C3 forms another low pass filter, whose main function is to remove AF components, thus providing a d.c. voltage whose amplitude is proportional to the carrier strength. This d.c. voltage is used to control the gain of the RF and IF amplifiers.
· For the practical diode detector shown in the Fig. 9.6, diode has d.c. load equal to R1 + R 2 , and the audio load impedance Z m equal to R1 in series with the parallel combination of R 2 , R 3 and R 4 , ignoring the capacitor reactance. Therefore, for practical envelope detector circuit maximum allowable modulation index can be given as R1 series with (R2 || R3 || R4 ) M max = R1 + R2
Ø
+
Derive the expression for FM.
VTU : March-2000, Marks 6
Df v = A sin éêwc t + sin wm t ùú = A sin [wc t + mf sin wm t] f m ë û
where,
wc = 2 p fc,
wm = 2 p fm
D f : Frequency deviation A : Amplitude of FM signal mf : Modulation index of FM
Ø
Define modulation index for FM.
Modulation in FM is generally expressed in terms of the modulation index. The modulation index is the ratio of the frequency deviation to the modulating frequency. Frequency deviation m f = Modulation index = Modulating frequency \
Ø
mf
=
Df d = fm fm
What is Carson's rule ?
· It is a matter of experience that the bandwidth requirements are determined by the maximum frequency deviation and maximum modulation frequency present in the complex modulating wave. We have, BW = 2 (m f + 1) f m BW = 2 (D f + fm max) \ In commercial FM broad casting, Maximum frequency deviation permissible = 75 kHz and then
Maximum modulating frequency = 15 kHz, Max BW FM = 2 [75 + 15] = 180 kHz. TM
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The above equation for calculating maximum bandwidth required to transmit the FM wave is known as Carson’s rule.
Ø
State the merits of FM over AM.
+
VTU : July-06, March-02, Aug.-04, 01, Marks 4
Frequency Modulation has the following advantages : 1. The amplitude of FM wave is constant, and hence transmitted power is constant, independent of modulation depth; whereas in A.M, modulation depth controls the transmitted power. This means that low level modulation can be employed in FM transmitters. Since the power is constant, the FM calculated signal, after low level modulation, can be amplified by more efficient class-C amplifiers. 2. In AM, 67 % of transmitted power is in the carrier, for maximum modulation depth, which is totally wasted as carrier does not carry any intelligence. In FM, all the transmitted power is useful. 3. FM receivers use amplitude limiter circuits to eliminate the amplitude variations caused by noise. Due to this, FM reception is more immune to noise than AM reception. 4. By increasing the frequency deviation in FM, it is possible to improve signal-to-noise ratio AM does not have this feature since in AM, modulation depth cannot be increased beyond 100 %. 5. For commercial FM transmitting stations a guard band of frequencies is allocated, this reduces adjacent channel interference, as compared to AM. 6. FM broadcasting is in the upper VHF and UHF frequency ranges. In these frequency ranges, there is inherently less noise than in the MW and SW ranges allotted to AM broadcast. 7. Since FM operates in VHF and UHF range, the propagation is line of sight propagation by space wave. The radius of operation of an FM transmitter is limited to radio horizon. This allows several independent FM transmitters to work on the same carrier frequency with very little interference than would be possible with AM.
Ø
+
State the demerits of FM over AM.
VTU : June-06, Marks 4
The following are some of the disadvantages of FM : 1. For transmission of FM signal, a much larger bandwidth is required than that required to transmit AM signal. 2. FM transmitter and receiver are quite complicated, especially from the point of view of servicing and fault finding/repairing of FM receivers. 3. Since FM reception is limited to radio horizon up to line of sight, the service area of FM transmitter is much less than that for AM.
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Although this is advantageous for reduction of adjacent channel interference, it is a disadvantage for FM mobile communication over a wide area.
Ø
Give comparison between FM and PM.
Sr. No.
FM
PM
1.
The equation for FM wave is : v = A sin [wc t + m f sin wm t ]
The equation for PM wave is v = A sin wc t + m p wm t
2.
The frequency deviation is linearly proportional to instantaneous amplitude of the modulating signal.
The phase shift of the carrier is linearly proportional to instantaneous amplitude of the modulating signal.
3.
Frequency modulation is direct method of producing FM signal.
Phase modulation is indirect method of producing FM.
4.
The modulation index of an FM signal is the ratio of the frequency deviation to the modulating frequency.
The modulation index is proportional to the maximum amplitude of the modulating signal.
5.
To have better quality of transmission and reception of higher audio frequencies, pre-emphasis and de-emphasis circuits are used.
The amount of frequency shift produced by a phase modulator increases with the modulating frequency. Hence an audio equalizer is required to compensate this.
6.
Amplitude of the FM wave is constant.
Amplitude of the PM wave is constant.
7.
Noise is better suppressed in FM systems as compared to PM system.
Noise immunity is inferior to that of FM.
8.
FM is mainly used for FM broadcasting used for entertainment purposes.
PM is used in mobile communication system.
Ø Sr. No.
[
+
Give the comparison between FM and AM.
FM
]
VTU : Nov.-10, Marks 5
AM
1.
The equation for FM wave is v = A sin [wc t + m f sin wm t ].
The equation for AM wave is v = Vc [1 + m sin wm t ] sin wc t.
2.
The modulation index can have value either less than one or more than one.
The value of modulation index is always between zero and one.
3.
Since in FM, amplitude of the carrier is constant, the transmitted power is constant, independent of the modulation index.
Transmitted power is dependent upon é m2 ù . modulation index PT = Pc ê1 + 2 ú ë û
4.
The modulation index determines the number of significant pairs of sidebands in an FM signal.
In an AM signal, only two sidebands are produced, for any value of modulation index.
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5.
The amplitudes of the carrier and side bands vary with the modulation index and can be calculated with Bessel functions.
The amplitudes of the sidebands is dependent on the modulation index, and is always less than the amplitude of carrier.
6.
The carrier or sideband amplitudes are zero at some modulation indices.
The sideband amplitude is never zero for any value of modulation index greater than zero.
7.
The bandwidth of an FM signal is proportional to the modulation index.
The bandwidth of an AM signal is twice the highest modulating frequency.
8.
For FM, the % of modulation is the ratio of the actual frequency deviation and the maximum permissible frequency deviation multiplied by 100.
For AM, % modulation is the ratio of amplitude of modulating voltage to the amplitude of the carrier multiplied by 100.
9.
The main advantage of FM over AM is its noise immunity, as limiter stage in FM receiver clips off noise signals.
The AM system is more susceptible to noise and more affected by noise than FM.
10.
The capture effect in FM allows the strongest signal on a frequency to dominate without interference from the other signal.
When two AM signals occupy the same frequency, both signals will generally be heard regardless of their relative signal strength.
11.
In FM, greater transmitter efficiency can be realized using class-C amplifiers, as amplitude of FM signal is constant.
The efficiency of AM is less than that of FM due to use of class-B amplifier.
12.
The bandwidth of FM signal is much under than the bandwidth of AM. The bandwidth of a typical FM channel is 200 kHz.
The bandwidth required to transmit AM signal is much less than that of FM typically 10 kHz in AM broadcasting.
13.
The circuits to produce and demodulate FM are usually more complex and expensive than AM circuits.
The demodulation of AM signal is very easy practically by use of a diode; which is very simple in operation and economical.
Important Examples Example 9.1 An audio frequency signal 10 sin 2 p ´ 500 t is used to amplitude modulate a
carrier of 50 sin 2 p ´ 105 . Calculate i) Modulation index.
ii) Sideband frequencies.
iii) Amplitude of each sideband frequencies.
iv) Bandwidth required.
v) Total power delivered to the load of 600 W. vi) Transmission efficiency. Solution : i) Modulation index : Given Vm = 10 sin 2 p ´ 500 t Vc = \
Vm =
50sin 2 p ´ 105 t 10 and Vc = 50 TM
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We know that, Modulation index m =
Vm 10 = = 0.2 Vc 50
and percentage modulation = 0.2 ´ 100 = 20 % ii) Sideband frequencies Given wm = 2 p ´ 500 \
fm =
500 Hz
and
wc =
2 p ´ 105
\
fc =
100 kHz
f USB = = and
f LSB = =
f c + f m = 100 kHz + 500 100500 Hz = 100.5 kHz f c – f m = 100 kHz – 500 99500 Hz = 99.5 kHz
iii) Amplitude of each sideband frequencies Amplitude of upper and lower sidebands =
0.2 ´ 50 mVc =5V = 2 2
iv) Bandwidth required BW = f USB – f LSB = 100500 – 99500 = 1000 Hz v) Total power delivered into a load 2 Vc 2 æ ç 1+ m We know that, PTotal = 2 2R ç è
of 600 W ö (50) 2 ÷ = ÷ 2 ´ 600 ø
2 ö æ ç 1+ (0.2) ÷ = 2.125 watts ç 2 ÷ è ø
vi) Transmission efficiency h = \
m2 2 + m2
=
(0.2) 2 2 + (0.2) 2
= 0.0196
h = 0.0196 ´ 100 = 1.96 %
%
Example 9.2 A broadcast transmitter radiates 20 kilowatts when the modulation percentage is
75. How much of this is carrier power ? Also calculate the power of each sidebands. Solution : We know that PTotal = \
Pc =
æ m 2 ö÷ Pc ç 1+ ç 2 ÷ è ø PTotal æ ö ÷ ç1 + ç 2 ÷ è ø m2
=
20
1 + (075 . )2
=
20 = 15.6 kW 1.28
2 TM
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Sideband power is given as æ m2 PSB = Pc ç ç 4 è \
PUSB =
æ (0.75) 2 ö ÷ = 15.6 ç ÷ ç 4 ø è
Communication Systems
ö ÷ = 2.2 kW ÷ ø
PLSB = 2.2 kW
Example 9.3 A carrier of 1 MHz with 400 W of its power is amplitude modulated with a
sinusoidal signal of 2500 Hz. The depth of modulation is 75 %. Calculate the sideband frequencies, the bandwidth, the power in the sidebands and the total power in the modulated
+
wave.
VTU : March-01, Feb.-04, Marks 5
Solution : Given : carrier frequency fc = 1 MHz = 1000 kHz and signal frequency fm = 2500 Hz = 2.5 kHz. \ Sideband frequencies fSB = fc + fm = 1000 + 2.5 and 1000 – 2.5 = 1002.5 kHz and 997.5 kHz Bandwidth = 1002.5 – 997.5 = 5 kHz Also power in carrier,
Pc = 400 W
Depth of modulation = m = 0.75 æ m2 Pt = Pc ç 1 + ç 2 è
Now,
æ (0.75) 2 ö ÷ = 400 ç 1 + ÷ ç 2 ø è
ö ÷ ÷ ø
Pt = 512.5 watts We know that, Power in sidebands = Total power – Carrier power = Pt – Pc = 512.5 – 400 = 112.5 watts Sideband frequencies are 1002.5 kHz and 997.5 kHz Bandwidth = 5 kHz Sideband power = 112.5 watts. Total power in the modulated wave = 512.5 watts. Example 9.4 Calculate the maximum allowable modulation index which may be applied to the
practical envelope detector circuit with following component values : R 1 =100 k W , R 2 = 200 k W, R 3 = 510 k W and R 4 = 1 M W. Solution : D.C. load for diode = R1 + R 2 = 100 k W + 200 k W = 300 k W TM
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9 - 18
Communication Systems
Z m = R1 + (R 2 | | R 3 | | R 4 ) = 100 + (200|| 510|| 1000) = 225.6 k W \
M max =
Zm 225.6 = = 0.752 Rc 300
Example 9.5 In an F.M. system, the frequency deviation constant is K = 5 kHz/V. If a
sinusoidal modulating signal of 15 V, 10 kHz is applied, calculate the peak frequency deviation and the modulating index. Solution : Given : 1) fm = 10 kHz 2) Frequency deviation constant = 5 kHz/V 3) \
AF voltage = 15 V Frequency deviation = 15 ´ 5 kHz Modulation index =
= 75 kHz
Df 75 kHz = 7.5 = fm 10 kHz
Multiple Choice Questions with Answers Introduction Q.1
Which of the following statements are true ? (a) Communication is the basic process of exchanging information. (b) Language and distance are the main limitations of human communication. (c) The first communication satellite was launched in 1962. (d) All of the above. (Ans. : d)
Elements of Communication Systems Q.1
In a communication system, noise is most likely to affect the signal _______. (a) at the transmitter
(b) in the channel
(c) in the information source
(d) at the destination (Ans. : b)
Q.2
The information signal from information source is converted into _____ signal by the transmitter. (a) mechanical
(b) physical
(c) optical
(d) electrical (Ans. : d)
Q.3
The undesirable electric signal which interferes with transmitted signal and may disturb the received signal is _____ . (a) noise signal
(b) voice signal
(c) modulating signal (d) audio signal (Ans. : a) TM
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Q.4
9 - 19
Baseband signals can also be referred as _____ . (a) modulating signals (b) carrier signals
Q.5
Communication Systems
(c) modulated signals (d) none of above. (Ans. : a)
Transducers which converts voice, picture or other form of signals into electrical signals forms part of _____ . (a) receiver
(b) transmitter
(c) mixer
(d) filters (Ans. : b)
Q.6
Baseband signals can be _____ . (a) only digital signals
(b) only analog signals
(c) analog or digital signals
(d) none of above (Ans. : b)
Modulation Q.1
In baseband transmission ______ signal is used for transmission. (a) original
(b) modulated
(c) carrier (Ans. : a)
Q.2
The transmission without modulation is called ______ transmission. (a) half duplex
(b) radio
(c) baseband (Ans. : c)
Q.3
Distance traveled by an electromagnetic wave during the time of one cycle is _______. (a) wavelength
(b) channel length
(c) wave distance (Ans. : a)
Q.4
Putting voice, video or information signal directly onto the communication medium is referred to as ______ transmission. (a) baseband
(b) broadband
(c) midband (Ans. : a)
Q.5
The spectrum space occupied by a signal is called ______. (a) bandwidth
(b) wavelength
(c) frequency band (Ans. : a)
Q.6
Unit of ________________ is angstrom. (a) wavelength of light (b) frequency of light (c) speed of light (Ans. : a)
Q.7
Indicate the false statement. Modulation is used to __________. (a) reduce the bandwidth used (b) allows multiplexing of signals (c) ensure that signal may be transmitted over long distances (d) allow the use of practicable antennas (Ans. : a)
Q.8
In modulation, the information signal is called ______ and the high frequency signal is called ______. (a) modulating signal, carrier
(b) carrier, modulated signal
(c) modulating, baseband signal (Ans. : a) TM
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Q.9
9 - 20
Communication Systems
Attenuation in the baseband signals is ______ as compared to modulated signals. (a) small
(b) same
(c) large (Ans. : c)
Q.10
Which of the following is not true in case modulation ? (a) It reduces antenna height.
(b) It avoids mixing of signals.
(c) It decreases range of communication.
(d) Improves quality of reception. (Ans. : c)
Q.11
The minimum antenna height is ______. (a) l/2
(b) l/4
(c) 4/l
(d) l (Ans. : b)
Q.12
The modulated signals can travel ______ distance as compared to baseband signals. (a) longer
(b) shorter
(c) same (Ans. : a)
Q.13
PAM is a type of ______ modulation. (a) pulse
(b) analog
(c) digital (Ans. : a)
Q.14
The height of antenna is_____ proportional to frequency used for the transmission. (a) not
(b) directly
(c) equally
(d) inversely (Ans. : d)
Q.15
The antenna height is given by _____ . (b) 4l
(a) l 4
(c) 2l
(d) l/2 (Ans. : a)
Q.16
_____ cannot be transmitted directly over long distance faithfully. (a) AM signals
Q.17
(b) FM signals
(c) Carrier signals
(d) Baseband signals. (Ans. : d)
To transmit baseband signal of frequency 15 kHz directly _____ meters of antenna height is required. (a) 7500
(d) 50
(c) 5000
(d) 10000 (Ans. : c)
Q.18
In amplitude modulation technique _____ of carrier signal is varied in accordance with the modulating signal. (a) frequency
(b) amplitude
(c) phase
(d) all of above (Ans. : b)
Amplitude Modulation Q.1
The AM signal that occupies the greatest bandwidths is the one modulated by ________ . (a) 1 kHz sine wave (c) 1 kHz square wave
(b) 10 kHz sine wave (d) 5 kHz square wave (Ans. : d)
Q.2
The carrier frequency is ______ the modulating frequency. TM
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(a) lower than
(b) higher than
Communication Systems
(c) same as (Ans. : b)
Q.3
When amplitude of carrier is varied in proportion with the instantaneous amplitude of modulating signal, we have_________ modulation. (a) amplitude
(b) frequency
(c) phase (Ans. : a)
Q.4
The outline of the peaks of the carrier signal is called ______ and it has the same shape as the ______. (a) carrier, modulating signal
(b) envelope, carrier
(c) envelope, modulating signal (Ans. : c)
Q.5
Which of the following modulating signal will occupy maximum bandwidth in AM ? (a) 5 kHz sine wave
Q.6
(b) 2 kHz square wave
(c) 10 kHz sine wave (Ans. : b)
AM broadcast takes place in the frequency range ______. (a) 535 - 1605 kHz
(b) 0 - 3 kHz
(c) 30 - 3 MHz (Ans. : a)
Q.7
In AM fc is ______ fm . (a) greater than
(b) lower than
(c) equal to (Ans. : a)
Q.8
Amplitude modulation is the process of ________. (a) superimposing a low frequency on a high frequency (b) superimposing a high frequency on a low frequency (c) carrier interruption (d) frequency shift and phase shift (Ans. : a)
Q.9
The depth of modulation is given by ______. (a) modulation index
(b) bandwidth
(c) deviation (Ans. : a)
Q.10
In AM the shape of ______ is same as that of the modulating signal. (a) carrier
(b) envelope
(c) information (Ans. : b)
Q.11
The modulation index is unitless. (a) True
(b) False (Ans. : a)
Q.12
If Em = 8 V, Ec = 10 V, the value of m is ______ for AM. (a) 0.8
(b) 8
(c) 0.2 (Ans. : a)
Q.13
In AM, the term (a) carrier
m Ec cos ( wc + wm ) represents ______. 2 (b) LSB
(c) USB (Ans. : c) TM
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Q.14
In AM, the term (a) carrier
9 - 22
Communication Systems
m Ec cos ( wc - wm ) represents ______. 2 (b) LSB
(c) USB (Ans. : b)
Q.15
The amplitude of both the sidebands in an AM wave is ______. (a) Ec2 / 2m
(b) m 2 Ec 2
(c) m Ec / 2 (Ans. : c)
Q.16
The modulation index of an AM wave is changed from 0 to 1. The transmitted power is _________. (a) unchanged
(b) halved
(c) doubled
(d) increased by 50 percent (Ans. : d)
Q.17
An amplitude modulated wave is __________. (a) the sum of the carrier and the modulating wave (b) the difference between the carrier and the modulating wave (c) the product of the carrier and the modulating wave (d) the sum of the carrier and its product with modulating signal. (Ans. : a)
Q.18
In an amplitude modulated waveform, the amplitude of sidebands is ______. (a) independent of the carrier amplitude (b) independent of the modulation index (c) carrier amplitude ´ modulation index (d)
1 carrier amplitude ´ modulation index 2 (Ans. : d)
Q.19
Overmodulation exists when modulation index is _____. (a) 1
(b) 0
(c) > 1 (Ans. : c)
Q.20
Q.21
Indicate the correct statement. _______ in AM. (a) Lower sideband power is constant
(b) Total transmitted power is constant
(c) Carrier power is constant
(d) Upper sideband power is constant (Ans. : c)
To achieve 80 percent modulation index with carrier ec = 20 cos wc t, the modulating signal amplitude Em should be ______. (a) 8 V
(b) 16 V
(c) 4 V (Ans. : b)
Q.22
To achieve faithful AM transmission ________________. (a) Em should be equal to Ec
(b) Em should be greater than Ec
(c) Em should be less than or equal to Ec
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(Ans. : c)
Basic Electronics
Q.23
9 - 23
For a carrier signal of 1 MHz and modulating signal of 20 kHz, what is the frequency range occupied by the AM signal ? (a) 980 kHz to 1020 kHz
Q.24
Communication Systems
(b) 0 kHz to 20 kHz
(c) 1000 kHz to 1020 kHz (Ans. : a)
For an AM wave represented by 20 [1+ 0.8 sin (2p ´ 2000 t) sin (2p ´ 106 t)] the sideband frequencies are : (a) 998 kHz and 1002 kHz
(b) 999 kHz and 1001 kHz
(c) 0.998 MHz and 1.002 MHz
(d) None of the above (Ans. : d)
Q.25
Expression of an AM wave is eAM = 50 [1+ 0.8 cos (400 p t)] cos
2 p ´ 105 t
then the
Em = ______. (a) 40 V
(b) 20 V
(c) 80 V (Ans. : a)
Q.26
Expression of an AM wave is eAM = 50 [1+ 0.8 cos (400 p t)] cos
2 p ´ 105 t
then the
modulation index m = ______. (a) 0.8
(b) 0.4
(c) 1 (Ans. : a)
Q.27
Number of frequency components in an AM wave are______. (a) 2
(b) 3
(c) 4 (Ans. : b)
Q.28
In AM the ______ does not carry any information. (a) carrier
(b) USB
(c) LSB (Ans. : a)
Q.29
The bandwidth of AM wave is ______. (b) 2 fm
(a) fm
Q.30
(c) fm / 2
(Ans. : b)
Expression of an AM wave is eAM = 50 [1+ 0.8 cos (400 p t)] cos 2 p ´ 105 t then the carrier frequency fc = ______. (a) 105 Hz
(b) 200 Hz
(c) 400 Hz (Ans. : a)
Q.31
Expression of an AM wave is eAM = 50 [1+ 0.8 cos (400 p t)] cos
2 p ´ 105 t
then the
modulating frequency fm = ______. (a) 105 Hz
(b) 200 Hz
(c) 400 Hz (Ans. : b)
Q.32
The relation between carrier power and total power in an AM wave is _______. æ m2 ö ÷ (a) Pc = PT çç1+ 4 ÷ è ø
æ m2 ö ÷ (b) Pc = PT çç1+ 2 ÷ è ø
æ m2 ö ÷ (c) PT = Pc çç1+ 4 ÷ è ø
æ m2 ö ÷ (d) PT = Pc çç1+ 2 ÷ è ø
+
VTU : Jan.-14
(Ans. : d) TM
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Q.33
Q.34
Q.36
Communication Systems
A single sideband signal contains 1 kW. Power contained in the sidebands is _______. (a) 0.25 kW
(b) 0.5 kW
(c) 1 kW
(d) none of the above
(Ans. : c) For a 100 % AM modulated wave with carrier suppressed, the percentage power saving will be ___________. (a) 100
Q.35
9 - 24
(b) 50
(c) 150
(d) 66.66
(Ans. : d) A carrier is simultaneously modulated by 2 sine waves with modulation indices of 0.6 and 0.8 ; the total modulation index __________. (a) 0.5
(b) cannot be calculated unless phase relations are known
(c) 1
(d) 0.7
(Ans. : c) For a signal amplitude modulated to a depth of 100 % by a sinusoidal signal, the power is _________. (a) same as the power of unmodulated signal (b) twice as the power of unmodulated signal (c) four times the power of unmodulated signal (d) one and a half times the power of unmodulated carrier (Ans. : d)
Q.37
An amplitude modulated voltage in volts is given by v = 20 (1 + 0.5 sin 6280 t) sin (6.28 ´106 ) t. The r.m.s. value of the unmodulated carrier voltage in volts is _______. (a) 20
(b) 20/ 2
(c) 10
(d) 10/ 2 (Ans. : b)
Q.38
In case the carrier of a 100 percent modulated AM wave is suppressed, the percentage power saving will be ________. (a) 33.33
(b) 66.66
(c) 100
(d) 150 (Ans. : b)
Q.39
Q.40
A carrier is simultaneously modulated by two sine waves with modulation indices of 0.3 and 0.4. The total modulation index will be ________. (a) 0.5
(b) 0.7
(c) 1
(d) cannot be ascertained unless phase relations are known. (Ans. : a)
A 200 W carrier is modulated to a depth of 75 percent. The total power of the modulated wave is given by _________. (a) 128 W
Q.41
(b) 156.3 W
(c) 256.25 W
(d) 288.33 W (Ans. : c)
A broadcast radio transmitter radiates 20 kW when the modulation percentage is 50. How much of this is carrier power ? (a) 4.23 W
(b) 8.47 W
(c) 12.7 W
(d) 16.94 W (Ans. : d)
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Q.42
9 - 25
Communication Systems
When E1, E2 ,E3 and E4 are the simultaneous modulating voltages, then the total modulating voltage will be _________. (a) E1 + E2 + E3 + E4
(b)
(c)
(d)
E1E2 + E2E4
E1 + E2 + E3 + E4 4 E12 + E22 + E23 + E24 (Ans. : d)
Q.43
A 1000 kHz carrier is simultaneously modulated with 300 Hz, 800 Hz and 2 kHz audio sine waves. The frequencies present in the output will be _______. (a) 1000 kHz, 300 Hz, 800 Hz and 2 kHz (b) 1800 kHz, 1300 kHz and 1002 kHz (c) 200 kHz, 1800 kHz, 700 kHz, 1300 kHz, 1002 kHz, 998 kHz and 1000 kHz (d) 998.0 kHz, 999.2 kHz, 999.7 kHz, 1000.3 kHz, 1000.8 kHz and 1002.0 kHz (Ans. : d)
Q.44
The principle used to transmit the signal is ________. (a) modulation
Q.45
(b) de-modulation
Q.47
(d) attenuation (Ans. : a)
The frequency of amplitude modulated signal is _____ the carrier signal. (a) less than
Q.46
(c) amplification
(b) more than
(c) same as
(d) none of above (Ans. : c)
AM wave have following components. (a) carrier, LSB and USB
(b) LSB and USB
(c) either LSB or USB
(d) one SB and vestige of other SB (Ans. : a)
The amplitude of LSB and USB generated in AM signal is _____ . (a) zero
(b) same
(c) different
(d) equal to amplitude of carrier (Ans. : b)
Q.48
The value of modulation index m is given as _____ . (a) Vc / Vm
(b)
Vc + Vm 2
(c) Vc + Vm
(d) Vm / Vc (Ans. : d)
Q.49
Q.50
The frequency of signals in AM technique ranges from _____ . (a) fc to (fc + fm )
(b) (fc – fm) to fc
(c) (fc – fm) to (fc + fm)
(d) fm to fc
(Ans. : c)
The peak voltage of carrier signal and modulating signal are given as 2 V and 1 V respectively, the modulation index m is _____ . (a) 0.5
(b) 2
(c) 1
(d) 0.25 (Ans. : a)
Q.51
Bandwidth of AM signals can be calculated if _____ . (a) value of only carrier frequency is known TM
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Communication Systems
(b) value of only modulating frequency is known (c) value of only sideband frequency is known (d) none of above (Ans. : b)
Q.52
If the amount of information is lost in particular AM signal then m for that signal is _____ . (a) more than 1
Q.53
(c) zero
(d) none of above (Ans. : a)
Bandwidth of AM signal is given as _____ the frequency of modulating signal. (a) half of
Q.54
(b) less than 1
(b) same as
(c) twice of
(d) four times (Ans. : c)
If sine wave of 4 V peak with frequency of 1000 Hz amplitude modulates the carrier wave of 10 V peak with 100 kHz frequency, the bandwidth of AM wave is _____ . (a) 200 kHz
(b) 99 kHz
(c) 101 kHz
(d) 2 kHz (Ans. : d)
Q.55
The modulation index m in AM interms of maximum and minimum voltages in resultant AM wave is given as _____ . V + Vmin V - Vmin V V (b) max (c) max (a) max (d) min Vmax - Vmin Vmax + Vmin Vmin Vmax (Ans. : b)
Q.56
If maximum and minimum value of voltages in amplitude modulated wave are 6 V and 2 V respectively the value of m is _____ . (a) 0.5
(b) 2
(c) 3
(d) 0.33 (Ans. : a)
Q.57
We can refer information power as _____. (a) power in carrier
(b) total power of AM wave
(c) power of two side bands
(d) none of above. (Ans. : c)
Q.58
If broadcast transmitter radiates 20 kW out of which carrier power is 12 kW what will be the power of each side band ? (a) 8 kW
(b) 2 kW
(c) 32 kW
(d) 4 kW (Ans. : d)
Q.59
For 100 % modulation the maximum total power of AM wave is _____ of carrier power Pc . (a) same as
(b) twice of
(c) 1.5 times
(d) half (Ans. : c)
Q.60
A 400 watt carrier is modulated with modulation index m = 1, the total power in AM wave is _____ . (a) 800 watt
(b) 600 watt
(c) 200 watt
(d) 400 watt (Ans. : b)
Q.61
The modulation index of an amplitude modulated wave is changed from 0 to 1. The transmitted power is _____ . (a) unchanged
(b) halved
(c) doubled
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(d) increased by 50 %. (Ans. : d)
Basic Electronics
Q.62
9 - 27
Communication Systems
If carrier is simultaneously modulated by 2 sine waves with modulation indices of 0.3 and 0.4 total modulation index will be _____ . (a) 0.5
(b) 0.7
(c) 0.25
(d) 1 (Ans. : a)
Q.63
Total modulation index m t is determined as _____ when one or more sine waves amplitude modulates the carrier wave. (a) m12 + m 22 + ...
(b) (m1 + m 2 + .... )2
m12 + m 22 + ... 2
(c)
(d)
m12 + m 22 + ... (Ans. : d)
Q.64
Which type of amplifier is used for collector modulator to generate AM signal ? (a) Class B push-pull amplifier.
(b) Class A-B amplifier.
(c) Class C amplifier
(d) None of the above. (Ans. : c)
Q.65
In low level AM systems amplifiers next to the modulating stages must be _____ . (a) non linear amplifier
(b) class A linear amplifiers
(c) class C amplifiers
(d) none of above (Ans. : b)
Q.66
In high level AM modulation circuitry has to handle _____ power. (a) high power
Q.67
(b) low power
(c) very low power
(d) none of above (Ans. : a)
Normal AM system can be referred as _____ . (a) DSBSC
(b) SSB
(c) DSB
(d) DSBFC (Ans. : d)
Q.68
In normal AM wave the information is present _____ . (a) in carrier component
(b) only in LSB component
(c) in LSB and USB component
(d) only in USB component (Ans. : c)
Q.69
In AM for faithful reception of original information signal atleast _____ has to be transmitted. (a) single SB
(b) single SB and carrier
(c) both SB
(d) both SB and carrier (Ans. : a)
AM Detection (Demodulation) Q.1
In diode detector circuit diode acts as ________. (a) full wave rectifier
(b) half wave rectifier
(c) switch
(d) amplifier (Ans. : b)
Q.2
In practical diode detector _______ of modulated wave is detected. (a) both positive and negative envelope
(b) positive envelope
(c) negative envelope
(d) none of above (Ans. : c)
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Frequency Modulation Q.1
The noise immunity of AM system is _________. (a) poor
(b) moderate
(c) excellent (Ans. : a)
Q.2
When frequency of carrier is varied in proportion with the instantaneous amplitude of modulating signal, we have_________ modulation. (a) amplitude
(b) frequency
(c) phase (Ans. : b)
Q.3
The ________ of FM or PM wave is constant. (a) frequency
Q.4
(d) bandwidth (Ans. : a)
(c) fc + d
(b) fc - d
(Ans. : c)
The modulation index of FM is given by _________. (a) m f = fm d
Q.6
(c) amplitude
The maximum frequency of FM wave is _________. (a) fc
Q.5
(b) phase
(b) m f = fm ´ d
(c) m f = d fm
(Ans. : c)
The BW of FM system is ________ that of AM. (a) lower than
(b) higher than
(c) same as (Ans. : b)
Q.7
According to Carlson's rule the BW of FM is_________. (a) BW = 2 [d + fm ]
Q.8
(c) BW = [d + 2 fm ]
(Ans. : a)
In FM, the BW depends on ________. (a) m, fm
Q.9
(b) BW = [2d + fm ]
(b) fc , fm
(c) m, Em
(Ans. : a)
The advantage of FM is _________. (a) its amplitude is constant
(b) it requires large BW
(c) its transmitter and receiver circuitry is quite complicated (Ans. : a)
Q.10
In AM all transmitted power is useful. (a) True
(b) False (Ans. : b)
Q.11
In frequency modulation, the modulation index is proportional to ________. (a) w m
(b)
1 wm
(c)
1 w2m
where wm is the modulation frequency in radians/second.
Q.12
(d) w2m
(Ans. : b)
A 4 volt peak audio modulating signal changes the carrier frequency from 200 kHz to 210 kHz, the frequency deviation is _________. TM
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(a) 5 kHz
9 - 29
(b) 10 kHz
Communication Systems
(c) 15 kHz
(d) 20 kHz (Ans. : b)
Q.13
Bandwidth in FM transmission with Df = 75 kHz, fm = 15 kHz is ________. (a) 120 kHz
(b) 140 kHz
(c) 160 kHz
(d) 180 kHz (Ans. : d)
Q.14
In an FM system, when the audio frequency is 500 Hz and AF voltage is 2.4 V, the deviation is 4.8 kHz. If the AF voltage is now increased to 7.2 V, the new deviation will be _________. (a) 10.2 kHz
Q.15
(b) 14.4 kHz
(c) 16.6 kHz
(d) 18.8 kHz (Ans. : b)
A 25 MHz carrier is modulated by a 400 Hz audio sine wave. The carrier voltage is 4 V and the maximum deviation is 10 kHz. The modulation index will be ________. (a) 2.5
(b) 5
(c) 15
(d) 25 (Ans. : d)
Q.16
In frequency modulation for a given frequency deviation, the modulation index varies ________. (a) inversely as the modulating frequency (b) directly as the modulating frequency (c) independent of the changes in modulating frequency (Ans. : a)
Q.17
In FM, the frequency deviation is _________. (a) proportional to modulating frequency (b) proportional to amplitude of modulating signal (c) constant
(d) zero (Ans. : b)
Q.18
In the spectrum of a frequency modulated wave (a) the carrier frequency cannot disappear (b) the total number of sidebands depends on the modulation index (c) the carrier frequency disappears when the modulation index is large (d) the amplitude of any sideband depends on the modulation index (Ans. : d)
Q.19
In which of the following modulation system when the modulating frequency is doubled, the modulation index reduces to half while modulating voltage remains constant ? (a) Phase
Q.20
(b) Amplitude
(c) Frequency
(d) None of the above (Ans. : c)
In FM signal, the power _________. (a) increases as the modulation index increases (b) reduces as the modulation index increases (c) increases as the modulation index decreases (d) remains constant when the modulation index increases (Ans. : d) TM
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Communication Systems
Q.21
A FM signal with modulation index Mf is passed through a frequency doubler. The wave in the output of the doubler will have a modulation index of _______. M (b) f (c) 2 M f (d) 4 M f (a) M f 2 (Ans. : c)
Q.22
A 500 Hz modulating voltage fed into an FM generator produces a frequency deviation of 2.25 kHz. The modulation index will be _______. (a) 2.25
(b) 4.5
(c) 6.77
(d) 8.00 (Ans. : b)
Q.23
If the amplitude of the voltage is kept constant, but its frequency is raised to 6 kHz, the new deviation will be _________. (a) 13.5 kHz
(b) 27 kHz
(c) 54 kHz
(d) 108 kHz (Ans. : c)
Q.24
Q.25
In an FM waveform, the sidebands are spaced at interval equal to ________. (a) four times the modulating frequency
(b) twice the modulating frequency
(c) half the modulating frequency
(d) equal to the modulating frequency (Ans. : c)
An FM signal with a modulation index m is passed through a frequency triple. The wave in the output of the tripler will have a modulation index of ________. (a) m/3
(b) m
(c) 3 m
(d) 9 m (Ans. : c)
Q.26
A 4 volt peak audio modulating signal changes the carrier frequency from 200 kHz to 210 kHz, the frequency deviation is _________. (a) 5 kHz
(b) 10 kHz
(c) 15 kHz
(d) 20 kHz (Ans. : b)
Q.27
In FM system, if the depth of modulation is doubled, the output power _______. (a) increases by factor of
(b) increases by factor of
2
(c) increases by factor of 2
3
(d) remains at unmodulated value (Ans. : d)
Q.28
In FM wave the information is contained in _________. (a) amplitude variations
(b) frequency variations
(c) carrier (Ans. : b)
Q.29
The amount of deviation in FM is directly proportional to ________ of the modulating signal. (a) amplitude
(b) frequency
(c) phase (Ans. : a)
Q.30
The number of significant sidebands in FM depends on _________. (a) modulation index
(b) deviation
(c) carrier frequency (Ans. : a)
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Q.31
9 - 31
Communication Systems
The equation of the FM signal is 10 sin [2 p ´ 106 t + 5 sin (4 p ´ 103 t)]. The modulating frequency is _________. (a) 106 Hz
(b) 5 Hz
(c) 2000 Hz (Ans. : c)
Q.32
The drawback of FM is _________. (a) its amplitude is constant
(b) it requires large BW
(c) it allows to improve S/N ratio (Ans. : b)
Q.33
The main disadvantage of FM is ________. (a) adjacent channel interference
(b) limited line of sight range
(c) complex circuitry
(d) low operating range (Ans. : b)
Q.34
In FM transmission, if frequency of modulating signal is doubled, the modulation index will _________. (a) be halved
Q.35
(b) be doubled
(c) be 4 times
(d) remain unchanged (Ans. : a)
Carrier frequency is __________ in FM wave e = 12 sin (6 ´108 t + 5 sin 1250 t) (a) 75.5 MHz (b) 85.5 MHz (c) 95.5 MHz
(d) 180 kHz (Ans. : c)
Q.36
Which of the following is the advantage of frequency modulation over amplitude modulation ? (a) Noise can be reduced by increasing deviation. (b) The amplitude of the FM wave in FM is independent of the depth of modulation, whereas in AM it is dependent on this parameter. (c) There is a large increase in noise to signal ratio in FM. (d) All of the above. (Ans. : d)
Q.37
Which one of the following is not necessarily an advantage of FM over AM ?
Q.38
(a) Lower bandwidth is required.
(b) Less modulating power is required.
(c) Better noise immunity is provided.
(d) The transmitted power is more useful. (Ans. : a)
On an FM signal, maximum deviation occurs at __________ . (a) zero crossing point (c) peak negative amplitude
(b) peak positive amplitude (d) both (A) and (B). (Ans. : b)
Phase Modulation Q.1
In PM _________ of carrier signal is varied in accordance with instantaneous value of modulating signal. (a) frequency
(b) amplitude
(c) phase
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(d) none of above (Ans. : c)
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Q.2
9 - 32
Communication Systems
For phase modulated signal maximum frequency deviation takes place ______of modulating signal. (a) at positive peak
(b) at negative peak
(c) at positive and negative peak
(d) near zero crossing (Ans. : d)
Q.3
Modulation index m p in phase modulation is proportional to _____________. (a) maximum amplitude of modulating signal (b) minimum amplitude of modulating signal (c) instantaneous value of modulating signal (d) none of above (Ans. : a)
Q.4
In phase modulation carrier frequency deviation is proportional to ____________. (a) only modulating voltage
(b) only modulating frequency
(c) modulating voltage and modulating frequency both (d) none of above (Ans. : c)
Q.5
The unit of modulation index mp in phase modulation is ________. (a) radians
(b) kHz / volts
(c) kHz
(d) volts (Ans. : a)
Q.6
The equation of the modulated wave for PM will be__________. 6
(a) 4 sin (1.57 ´ 10 t) 6
6
(c) 4 sin (1.57 ´ 10 t + 25 sin 2513 t)
Q.7
6
(b) 4 sin 800 t + 4 sin 50 ´ 10 t
(d) 4 sin (1.57 ´ 10 t – 25 sin 2513 t) (Ans. : c) The difference between PM and FM is_________.
(a) in the poorer audio response of phase modulation (b) purely theoretical otherwise the two are modulation (c) merely in the different modulation indices (d) too great to make the two systems compatible (Ans. : c)
Q.8
The frequency deviation of FM signal produced from PM is ___________. (a) same as that of FM signal produced by direct method (b) more than that of FM signal produced by direct method (c) directly proportional to peak amplitude and the frequency of modulating signal (d) directly proportional to peak amplitude of modulating signal (Ans. : c)
Q.9
One way to derive FM from PM : (a) Integrate the modulating signal before applying to PM oscillator. (b) Integrate signal out of PM oscillator. (c) Differentiate the modulating signal before applying to the PM oscillator. (d) Differentiate the signal out of PM oscillator. (Ans. : a) TM
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Q.10
9 - 33
Communication Systems
In PM system maximum frequency deviation results at __________. (a) zero crossing
(b) peak negative amplitude
(c) peak positive amplitude
(d) all of above (Ans. : a)
Q.11
Q.12
In PM signal frequency deviation of carrier is not proportional to ________. (a) modulator phase shift
(b) modulating signal frequency
(c) modulating signal amplitude
(d) carrier amplitude and frequency (Ans. : d)
Compensation for 'increase in carrier frequency deviation with an increase in modulating signal frequency is achieved by _______ circuit between modulating signal and phase modulator. (a) low pass filter
Q.13
(b) high pass filter
(c) phase shifter
(d) bandpass filter (Ans. : a)
If the amplitude of modulating signal given to the phase modulator circuit is constant, the output signal will be ______. (a) zero
(b) carrier frequency itself
(c) above carrier frequency
(d) below carrier frequency (Ans. : b)
Q.14
A phase modulator varies the phase shift of the _________. (a) carrier
(b) modulating signal
(c) both carrier and modulating signal
(d) none of above (Ans. : a)
Q.15
The small change in frequency produced by phase modulator can be increased by using ________. (a) amplifier
(b) mixer
(c) frequency multiplier
(d) frequency divider (Ans. : c)
Q.16
The oscillator whose frequency is varied by an input voltage is called as ________. (a) VXO
(b) VCO
(c) VFO
(d) VHF (Ans. : b)
Q.17
Which type of oscillators are preferred for carrier generation because of their good frequency stability ? (a) LC
(b) RC
(c) LR
(d) Crystal (Ans. : d)
Comparison between FM and AM Q.1
The AM system is _________ immune to noise than the FM. (a) more
(b) less
(c) equally (Ans. : b)
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Q.2
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Communication Systems
Which of the following is the disadvantage of FM over AM ? (a) A much wider channel is required by FM as compared to that for AM. (b) The area of reception is limited. (c) The modulating and demodulating equipment is complex. (d) All of the above. (Ans. : d)
Q.3
Which of the following is the advantage of frequency modulation over amplitude modulation ? (a) Noise can be reduced by increasing deviation (b) The amplitude of the FM wave in FM is independent of the depth of modulation, whereas in AM it is dependent on this parameter (c) There is a large increase in noise to signal ratio in FM (d) All of the above (Ans. : d)
Q.4
The main disadvantage of FM is _______. (a) expensive and complex
(b) excessive use of spectrum space
(c) less noise immunity
(d) lower efficiency (Ans. : b)
Q.5
Main disadvantage of FM over AM is________. (a) very high modulating power is needed
(b) high output power is required
(c) large bandwidth is required (d) for high frequency signals noise is very high (Ans. : c)
Q.6
Which of the following is not a major benefit of FM over AM ? (a) Capture effect
(b) Greater efficiency
(c) Better noise immunity
(d) Reduced complexity and cost (Ans. : a)
Q.7
Bandwidth of FM signal is _____ than AM signal. (a) lesser
(b) either lesser or larger
(c) larger
(d) none of above (Ans. : c)
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10
Telephone Systems and Optical Fibre Communication Chapter at a Glance
Important Definitions 1. Full-duplex system : Both parties can communicate simultaneously. 2. Tandem office : Tandem office connects the central offices that do not have any trunk line connection between them. 3. Pulse dialing : Initially, the telephone system used to dial a call by breaking the loop circuit at a 10 Hz rate with the number of interruptions equal to the number dialed. This method is known as pulse dialing. 4. Dual Tone Multi-Frequency (DTMF) : To dial a call Dual Tone Multi-Frequency (DTMF) dialing method is used. In this method, a particular number is represented by two different tones/frequencies. Thus, when predefined combination of two frequencies occur, the corresponding number is dialed. 5. Cell in a mobile communication system : The basic concept behind the cellular radio system is that rather than serving a given geographical area within a single transmitter and receiver, the system divides the service area into many small areas known as cells. 6. Fiber Optic Communication : The communication method in which transmission of information takes place in the form of light signal with the help of optical fiber is called fiber optic communication.
Important Questions and Answers
Ø
Write a note on ISDN.
· ISDN was developed by ITU-T in 1976. ISDN is a protocol that combines both digital telephony and data transport services. · ISDN is a digital communication interface designed to replace the existing local analog Public Switched Telephone Networks (PSTN).
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Telephone Systems and Optical Fibre Communication
· ISDN incorporates voice, data, video and fascimile information on the same common carrier. It is an advanced set of telecommunication series based on existing telephone networks. ISDN is an infrastructure to support a wide variety of services. The data format is totally digital. · The voice and data transmission is integrated over one system.
Ø
Explain the types of services.
· The services available through ISDN include 1. Bearer services 2. Teleservices 3. Supplementary services Services
Bearer services Circuit switching Packet switching Frame switching Cell switching
Teleservices
Supplementary services
Telephony
Call waiting
Telefax
Reverse charging
Teletex Telex
Message handling
Teleconferencing
Fig. 10.1
Ø
Explain BRI channel.
· BRI channel consists of 2 bearer channels (B) and 1 data control (D) channel. These channels are time multiplexed on line. The BRI channel denoted by (2B + D). Fig. 10.2 shows BRI channel.
Basic rate
2B + D
Fig. 10.2 BRI channel
· B-channel supports data rate of 64 kbps and D-channel supports data rate of 16 kbps. The total data rate of (2B + D) channel can be 144 kbps. With framing control, the data rate can be 192 kbps. · All configurations of communication are possible i.e. simplex, half duplex and duplex. The standard allows the B channels to be further multiplexed in sub-channels. TM
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Ø
10 - 3
Telephone Systems and Optical Fibre Communication
Explain PRI channel.
· The PRI channel consists of 23 bearer (B) and 1 data control (D) channel. These channels are time multiplexed on line. The PRI channel is denoted by 23 B + D. Fig. 10.3 shows PRI channel. 1 2 23
23B+D
Primary rate
D
Fig. 10.3 PRI channel
· Total bandwidth of PRI channel is 1.536 Mbps. The primary rate service is T 1 compatible.
Ø
What are the disadvantages of fiber optic system ?
1. High initial cost : The initial installation or setting up cost is very high compared to all other systems. 2. Maintenance and repairing cost : The maintenance and repairing of fiber optic systems is not only difficult but expensive also.
Multiple Choice Questions with Answers The Telephone Systems Q.1
Which of the following statements are true ? (a) Telephone and broadcastings systems are same. (b) The telephone signaling and current, voltage levels in subscriber line vary according to the transmission system used. (c) Compatibility of two different telephone systems is maintained by keeping consistency in telephone signaling and current, voltage levels in the subscriber line (d) None of these (Ans. : c)
Q.2
In a telephone system, subscribers are connected to ______ so as to communicate with other subscribers. (a) central office
Q.3
(b) control office
(d) exchange office (Ans. : a)
In a telephone system ____ is used for communication between two subscribers connected to same central office. (a) trunk line
Q.4
(c) tandem office
(b) local loop
(c) tandem office
(d) central office switch (Ans. : d)
The two central offices of a telephone system are interconnected with the help of _____. (a) central office switch
(b) trunk line TM
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Telephone Systems and Optical Fibre Communication
(c) central office
(d) subscriber (Ans. : b)
Q.5
In a telephone system, ____ acts as a connecting media when there is no trunk line connection between two central offices. (a) tandem office
Q.6
(b) subscriber
(b) coaxial cable
(c) fiber optic cable
(d) all of these (Ans. : a)
Use of twisted pair cable eliminates ______ in a telephone communication. (a) crossover dialing
Q.8
(d) central office (Ans. : a)
Subscribers of a telephone system are connected to central office with the help of a single ______. (a) twisted pair cable
Q.7
(c) local loop
(b) crosstalk dialing
(c) pulse dialing
(d) none of these (Ans. : b)
In pulse dialing method, the breaking of loop circuit was done at _____ rate. (a) 10 Hz
(b) 20 Hz
(c) 10 KHz
(d) 20 KHz (Ans. : a)
Q.9
DTMF stands for _____. (a) Dial Tone Multi-Frequency
(b) Dial Terminal Multi-Frequency
(c) Dual Tone Multi-Frequency
(d) Dual Time Multi-Frequency (Ans. : c)
Q.10
Telephone instruments use _____ as transmitter and ____ as receiver. (a) magnetic earphones, carbon microphones (b) magnetic microphones, carbon earphones (c) carbon microphones, magnetic earphones (d) carbon earphones, magnetic microphones (Ans. : c)
Q.11
Telephone communication is ______ communication. (a) simplex
(b) half duplex
(c) full duplex
(d) none of these (Ans. : c)
Principle of Operations of Mobile Phone Q.1
In mobile communication, the system divides the service area into many small areas known as ______. (a) unit
(b) cell
(c) MSC
(d) MTSO (Ans. : b)
Q.2
In mobile communication MSC means _____. (a) Mobile Service Center
(b) Mobile Switching Center
(c) Mobile Service Control
(d) Mobile Switching Control (Ans. : b)
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Q.3
10 - 5
In mobile communication, MSC is also known as ______. (a) MSTO
Q.4
(b) MTSO
(b) 800 - 900 MHz
(d) none of these (Ans. : b)
(c) 600 - 800 kHz
(d) 800 - 900 kHz (Ans. : b)
In a cellular transmitter there are _____ transmit channels. (a) 666 30 KHz
Q.6
(c) MISO
The cellular system operates in the _____ range. (a) 600 - 800 MHz
Q.5
Telephone Systems and Optical Fibre Communication
(b) 500 20 KHz
(c) 666 30 MHz
(d) 500 30 MHz (Ans. : a)
In a cellular transmitter ____ circuit sets the transmitter to one of 8 power output levels. (a) phase modulator
(b) directional coupler (c) APC
(d) Duplexer (Ans. : c)
Q.7
In a cellular transmitter, for proper isolation the transmit and receive frequencies are spaced _____ apart from each other. (a) 40 Hz
Q.8
(b) 45 KHz
(c) 45 MHz
(d) none of these (Ans. : c)
What is the range of cellular receiver ? (a) 825.03 MHz to 844.98 MHz
(b) 870.03 MHz to 889.98 MHz
(c) 825.03 kHz to 844.98 MHz
(d) 870.03 kHz to 889.98 kHz (Ans. : b)
Integrated Services Digital Network (ISDN) Q.1
Q.2
ISDN stands for _____. (a) Integrated Services Digital Network
(b) International Subscribers Digital Network
(c) Integrated Subscribers Digital Network
(d) International Services Digital Network. (Ans. : a)
ISDN has ___ types of services. (a) two
(b) three
(c) four
(d) six (Ans. : b)
Q.3
In _____ of ISDN, the information content remains unchanged. (a) bearer services
(b) teleservices
(c) supplementary services
(d) both (a) and (b) (Ans. : a)
Q.4
Teleconferencing is an example of _____. (a) supplementary services
(b) bearer services
(c) teleservices
(d) all of these (Ans. : c)
Q.5
Call waiting, reverse charging come under ______. (a) bearer services
(b) supplementary services
(c) teleservices
(d) all of these (Ans. : b) TM
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Q.6
Telephone Systems and Optical Fibre Communication
In ISDN, each user is linked to the central office through _____. (a) trunk lines
Q.7
10 - 6
(b) digital pipes
(c) both (a) and (b)
(d) none of these (Ans. : b)
What is the data rate of B channels in ISDN ? (a) 16 kbps
(b) 64 kbps
(c) 384 kbps
(d) 74 kbps (Ans. : b)
Q.8
In ISDN, D channels have data rate _____. (a) 16 kbps
Q.9
(c) 74 kbps
(d) both (a) and (b) (Ans. : d)
______ channels are available with data rates of 384 kbps, 1536 kbps or 1920 kbps. (a) B
Q.10
(b) 64 kbps
(b) D
(c) H
(d) all of the above (Ans. : c)
PSTN stands for _____. (a) Public Switched Telephone Networks. (b) Priority Switched Telephone Networks. (c) Public Switched Telecommunication Networks. (d) Public Subscribed Telephone Network. (Ans. : a)
Q.11
NT2 and NT1 are interconnected by ______ and is then known as ISDN interface. (a) T-bus
Q.12
(b) S-bus
(c) U-bus
(d) none of these (Ans. : a)
In ISDN interface, communication devices are connected to NT2 by _____. (a) T-bus
(b) S-bus
(c) U-bus
(d) N-bus (Ans. : b)
Q.13
BRI channel of ISDN interface consists of _______ B channel and _____ D channel. (a) 1, 2
(b) 2, 1
(c) 3, 1
(d) 1, 3 (Ans. : b)
Q.14
BRI channel of ISDN interface is denoted by _____. (a) 2B + D
(b) 2D + B
(c) B + D
(d) 2B – D (Ans. : a)
Q.15
For ISDN interface, total data rate of BRI channel can be ______. (a) 124 kbps
Q.16
(b) 120 kbps
(c) 140 kbps
(d) 144 kbps (Ans. : d)
In ISDN interface, PRI channel consist of ______ B channel and ____ D channel. (a) 23, 1
(b) 1, 23
(c) 2, 1
(d) 1, 2 (Ans. : a)
Q.17
BRI and PRI channels of ISDN interface are ______ multiplexed on line. (a) time
Q.18
(b) frequency
(c) code
The PRI channel of ISDN interface is denoted by ____.
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(d) all of the above (Ans. : b)
Basic Electronics
10 - 7
(a) 23B + D
Telephone Systems and Optical Fibre Communication
(b) B + 23D
(c) 2B + D
(d) B + 2D (Ans. : a)
Q.19
Total bandwidth of PRI channel of ISDN interface is ______. (a) 1.536 Mbps
(b) 1.536 kbps
(c) 1.536 bps
(d) none of these (Ans. : a)
Fiber Optic Communication Q.1
The transmission medium in optical fiber communication system is ______. (a) twisted pair cable
Q.2
(c) optical fiber cable (d) all of the above (Ans. : c)
In optical communication system, ______ converts the electrical analog or digital signal into its corresponding optical signal. (a) optical transmitter
Q.3
(b) coaxial cable
(b) optical receiver
(c) light detector
(d) light source. (Ans. : a)
In fiber optic communication, _______ regenerates the signal by restoring its power and removing noise. (a) regenerator
(b) repeater
(c) receiver
(d) regulator (Ans. : b)
Q.4
Fiber cables are made up of _____. (a) copper cables
(b) aluminum cable
(c) silica glass
(d) all of the above (Ans. : c)
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Telephone Systems and Optical Fibre Communication
Notes
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