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G NARAYANAMMA INSTITUTE OF TECHNOLOGY & SCIENCE
(FOR WOMEN) SHAIKPET, HYDERABAD – 500008
ELECTRONIC CIRCUITS LABORATORY MANUAL
DEPARTMENT OF
ELECTRONICS & COMMUNICATION ENGINEERING MARCH - 2006
G NARAYANAMMA INSTITUTE OF TECHNOLOGY & SCIENCE
(FOR WOMEN) SHAIKPET, HYDERABAD – 500008
GNITS GNITS-D / ECE / LLM / 023(a) / 01 LAB WISE-LABMANAUALS DEPARTMENT : ECE
ELECTRONIC CIRCUITS LABORATORY MANUAL
DEPARTMENT OF
ELECTRONICS & COMMUNICATION ENGINEERING MARCH - 2006
INDEX
S.NO NAME OF THE EXPERIMENT PAGE.NO
SOFT WARE
1. COMMON EMITTER AND COMMON SOURCE 1
AMPLIFIER.
2. TWO STAGE RC COUPLED AMPLIFIER. 9
3. CURRENT SHUNT AND FEED BACK AMPLIFIER 16
4. RC PHASE SHIFT OSCILLATOR. 21
5. CLASS A AND CLASS AB POWER AMPLIFIERS 25
6. HIGH FREQUENCY COMMON BASE AMPLIFIER. 32
HARD WARE
7. TWO STAGE RC COUPLED AMPLIFER 38
8. CURRENT SHUNT AND FEED BACK AMPLIFIER 41
9. CLASS A AND CLASS AB POWER AMPLIFIERS. 44
10. SINGLE TUNED VOLTAGE AMPLIFIER 48
11. SERIES VOLTAGE REGULATOR 50
12. SHUNTVOLTAGE REGULATOR. 52
Ω=−
=−
=
Ω===∴
=+=+==−=−=∴
=×==∴
===
KI
VVR
KIVR
VVVVAIII
AII
AmII
R
BCC
R
B
REBEB
BRR
BR
CB
3125.40480
65.525
15.12465
65.565.5565.0&
46515480480153232
151903
11
22
12
1
µ
µ
µµµ
µβ
COMMON EMITTER AND COMMON SOURCE AMPLIFIER AIM: To design CE single stage amplifier with potential divider circuit using
NPN Transistor 2N2923 for the specifications : IC= 3 mA, Vce = 10v,β = 190,
& IR1 = 32IB .verify DC values (Voltage and current) at various nodes using
MULTISIM.
APPARATUS: - Multisim Soft ware. DESIGN PROCEDURE: Vcc = 25V
Select VRE ≤ VCE
Select VRE = 5V
)00.2(66.135 KselectKmI
VR
C
REE ===∴
& VRC=VCC-VCE-VRE=25-10-5=10V
Ω===∴ KmI
VR
C
RCC 33.3
310
25VVCC
Q12N2923
R140.2kOhm_1%
R212kOhm_5%
R32.00kOhm_1%
R440.2kOhm_1%
V10V
V2
0V
V30V
V40V
23
4
7
9 10
11
0
VCC
CIRCUIT DIAGRAM:- PROCEDURE:- 1. Rig up the circuit using multisim software and verify the
results using DC operating point analysis (simulate ---- analysis ----- DC
operating point).
2.Rig up the circuit using multisim software and verify the results using DC
transfer characteristic analysis(simulate ---- analysis ----- DC sweep)
Out put voltage VCE variation with V CC (0 to 25V)
RESULT:- The CE single stage amplifier is designed. The D.C voltages and
currents at various nodes are observed. The D.C transfer characteristic is
plotted.
COMMON SOURCE AMPLIFIER AIM: a) To design a single stage FET Common Source amplifier with potential
divider circuit using 2n4861 FET-N channel for the following specifications:
VDD = 24V,ID = 1ma,VGS=2V,VPMAX =13V,RL=1K.
b) To observe dc operating point, frequency response, DC transfer characteristic
& C.R.O waveforms.
APPARATUS: Multisim soft ware. DESIGN PROCEDURE: VDSmin = VPmax + 1 - VGS
= 13 + 1 - 2
= 12V
)7.4..5tan(
54120
20424
1
426
)3.6tan(616
62
12242
1
1
22
11
2
2
min
MeiMtoequalorthanlessiswhichvaluedardsUse
MM
R
VVV
RVV
R
MRSelect
VVVVV
KvaluedardsUseKmI
VRR
VVVV
GDDR
R
R
RGSSG
D
RDSD
DSDDRDS
Ω=×
=∴
=−=−=
×=
Ω=
==−=−=
ΩΩ====
=−
=−
==
CIRCUIT DIAGRAM:
PROCEDURE:- 1. Rig up the circuit using multisim software and verify the
results using DC operating point analysis (simulate----analysis ---- DC operating
point)
2.Rig up the circuit using multisim software and verify the results using DC
transfer characteristic analysis(simulate ---- analysis ----- DC sweep)
3. Rig up the circuit using multisim software and verify the results using AC
analysis (Simulate ---- analysis ----- AC analysis)
4.Rig up the circuit using multisim software and verify the results using Oscilloscope
RESULT: The CS single stage amplifier is designed with the given
specifications. The D.C operating point analysis is performed. The frequency
response is plotted and the Band width is found.
TEST YOUR SELF
1. What is meant by Q- point?
2. What is the need for biasing a transistor?
3. What factors are to be considered for selecting the operating point Q for
an amplifier?
4. Distinguish between D.C. and A.C load lines.
5. What are the reasons for keeping the operating point of a transistor as
fixed?
6. What is thermal runaway? How can it be avoided?
7. What are the factors which contribute to thermal instability?
8. Define ‘Stability Factor’. Why would it seem more reasonable to call this
an instability factor?
9. How will be the output voltage in a CS amplifier?
10. To have good voltage gain and high input resistance which FET amplifier
is to be used?
V10V
V20V
V3
0V
R132.98kohm
R25.1kohm
R32.2kohm
R4516ohm
Q1BC107BP
12VVCC
TWO STAGE RC COUPLED AMPLIFIER
Q1) Design a single stage transistor amplifier with potential divider circuit (using an npn si transistors) with following specifications. IC=1.6ma,VCE=7.6v,RC=2.2k,VCC=12v, I1=10IB and β=54. Verify the DC values (Voltage and current) at various nodes using Multisim software DESIGN: IB=IC/β = 1.62/54=0.03ma VCC=IC(RC+RE)+VCE ; 12=1.62(2.2+RE)+7.6 ; RE=0.516k
V2=VBE+ICRE ; V2=0.7+1.62*0.516=1.536v
V2=I1R2 ; R2=V2/(I1=10IB) ; 1.536/0.3=5.12k
I1=VCC/(R1+R2) ; (R1+R2)=12/0.3=38.1k ; R1=38.1-5.12=32.98k
CIRCUIT DIAGRAM: 5 1 8 4 2 0
PROCEDURE: Rig up the circuit using multisim software and verify the
results using DC operating point analysis (simulate analysis DC
operating point)
DC Operating Point (Results)
1 8.05632v
2 928.05352mv
4 1.58077v
Vv1#branch 315.92573µa
Vv2#branch 1.79258ma
vcc 12.00000v
vccvcc#branch -2.10851ma
Q2) Design a single stage transistor amplifier with potential divider circuit
(using an npn si transistors) with following specifications.
IC=2.32ma,VCE=5.7v,RC=2.2k,VCC=12v, I1=10IB and β=33. Verify the DC
values (Voltage and current) at various nodes using Multisim software DESIGN:
IB=IC/β = 2.32/33=0.07ma
VCC=IC(RC+RE)+VCE ; 12=2.32(2.2+RE)+5.7 ; RE=0.51k
V2=VBE+ICRE ; V2=0.7+2.32*0.51=1.88v
V2=I1R2 ; R2=V2/(I1=10IB) ; 1.88/0.7=2.68k
I1=VCC/(R1+R2) ; (R1+R2)=12/0.7=17.14k ; R1=17.14-2.68=14.46k
CIRCUIT DIAGRAM:
V10V
V20V
V3
0V
R114.46kohm
R22.68kohm
R32.2kohm
R4510ohm
Q1BC107BP
12VVCC
5
3
2
12
0
PROCEDURE: Rig up the circuit using multisim software and verify the results using DC operating point analysis (simulate analysis DC
operating point)
DC Operating Point (Results) 1 6.84857v 2 1.19817v 3 1.85869v
vv2#branch 2.34156ma vcc 12.00000v
vccvcc#branch -3.04290ma vv1#branch 701.33569µa vv3#branch -7.79614µa
Q3) Cascade above two stages and find overall gain (choose Cc=4.7µf, Ce=470µf, hfe=50) find the frequency response, DC operating points and parameter sweep of load resister. ANALYSIS: Stage-2: AI2= -hfe/(1+hoeRL2) ; -50/(1+2/40) = -47.62
Ri2 = hie+hreAI2RL2 ;1.1+2.5e-4*-47.62*2 = 1.076k;
Av2= -AI2*RL2/Ri2 ; -47.62*2/1.076 = -88.51 Stage-1: RL1 = 2.2k||14.2||2.5||1.076 = 0.54k AI1 = -50/(1+0.54/40) = -49.3 Ri1 = 1.1+2.5e-4*-49.3*0.54 = 1.106k Av1 = -49.3*0.54/1.106 = -24.07 Overall gain Av = Av1*Av2 = 24.07*88.51= 2130.4 Avs = Av*Ri’/(Ri’+RS) ; Ri’ = 1.106||33||5.1= 0.88k =2130.4*0.88/(0.88+15) =118 CIRCUIT DIAGRAM:
Rs
15kOhm_5%
C1
4.7uF
R25.1kOhm_5%
Rc1
2.2kOhm_5%
Re1
510Ohm_5%C2
470uF
C3
4.7uF
R12
14.0kOhm_1%
R222.55kOhm_1%
Re2
470Ohm_5%
Rc22.2kOhm_5%
C5
47uF
V11mV0.71mV_rms1000Hz0Deg
12VVCC
C4
470uF
R1022kOhm_5%
A BT
G
XSC1
R133kOhm_5%
Q3BC107BP
Q1BC107BP
1 2
0
9
VCC
14
3
5
10
11
15
Note: In above two stage CE amplifier, all resistor values are same as trainer kit values. PROCEDURE:1. Rig up the circuit using multisim software and verify the results using DC operating point analysis (simulate------- analysis ------- DC operating point and AC analysis)
DC Operating Point (Results)
Node no Voltage 2 1.57966 9 8.01593
15 926.65516m 5 1.83114 11 1.16896 10 6.54642
2. Rig up the circuit using multisim software and verify the results using Parameter Sweep(Simulate------ analysis ------- Parameter sweep)
RESULTS: Observed the DC voltages/currents for single stage and two stage
amplifiers. It is observed that Two stage amplifier gives a mid band gain of
1220.It is also observed that as load resistance is nearer to RC2, the out put
voltage is decreasing, since net load resistance is decreasing.
TEST YOUR SELF
1. What do you mean by a multi stage amplifier? Mention its need.
2. What are the objectives of coupling elements?
3. What are the effects of bandwidth in multistage amplifier?
4. What is the expression for the band width of multistage amplifier?
5. Why RC coupling is popular?
6. What are the advantages & disadvantages of RC coupled amplifier?
7. Define the terms BW, gain BW product and dynamic range of an
amplifier?
8. What is the effect of By pass capacitor in a RC coupled amplifier?
9. What is the use of transformer coupling in the output stage of multistage
amplifier?
10. What is a DC amplifier? What are its advantages and drawbacks?
CURRENT SHUNT FEEDBACK AMPLIFIER AIM: Design current shunt feed back amplifier with a feedback resistance 5K
using transistor BC 107. Obtain DC operating point and frequency response.
APPARATUS: Multisim software. DESIGN PROCEDURE:
71.115
2.266.11
66.1115.115
343.115.115)343.1)(085.0(11
343.1)8.0)(50)(67151.0)(50(
4)5470//(;8.01.14
4
67151.0076.12.2
2.2
50,50
085.04705
470
220
1
21
1
1
2
1
1
2
2
1
1
1
1
2
2
2
=×====∴
===
=+=+==−−=
=+==+
=+
=
=+
=+
−=
==−=−=
×××−
==
=+
=+
=−
=
KK
RR
ARIRI
VV
A
KDAA
KADKA
KKRRWhereKK
KhieR
RII
KKK
RRR
II
hFEII
hFEII
II
II
II
II
IIA
KRRR
II
S
CIF
SS
CO
SVF
IIF
I
I
SS
B
IC
C
C
C
B
C
B
C
S
B
B
C
C
B
B
C
S
RI
EF
E
E
F
β
β
R1
15kohm
R25.1kohm
R333kohm
R42.2kohm
R5510ohm
R62.55kohm
R714kohm
R8470ohm
R92.2kohm
R10
5kohm
C1
4.7uF
C4
4.7uF
12VVCC
V11mV0.71mV_rms1000Hz0Deg
Q1BC107BP
Q2BC107BP
R1122kohm
A BT
G
XSC1
C2
47uF
C3
470uF
2
35
4
6
7
0
8
VCC
11
1
CIRCUIT DIAGRAM:
PROCEDURE:- 1. Rig up the circuit using multisim software and verify the
results using DC operating point analysis (simulate ---- analysis ----- DC
operating point)
2. Rig up the circuit using multisim software and verify the results using Oscilloscope
3. Rig up the circuit using multisim software and verify the results using AC
analysis (simulate----- analysis----AC analysis)
4. Rig up the circuit using multisim soft ware and verify the results using
Parameter Sweep(Simulate ---- analysis ----- Parameter Sweep)
RESULT: The current shunt feed back amplifier is designed with feed back
resistance of 5KΩ . The DC operating point values are obtained and the
frequency response is plotted.
TEST YOUR SELF
1. What is feedback in Amplifiers?
2. Explain the terms feed back factor and open loop gain.
3. What are the types of feedback?
4. Explain the term negative feedback in amplifiers?
5. What are the disadvantages of negative feedback?
6. What are the advantages of negative feedback?
7. When will a negative feedback amplifier circuit be unstable?
8. Compare the negative feedback and Positive feedback.
9. Give the expression for closed loop gain for a negative feed back
amplifier?
10. How does negative feedback reduce distortion in an amplifier?
11. How does series feedback differ form shunt feedback?
12. What is the difference between voltage feedback and current feedback?
RC PHASE SHIFT OSCILLATOR
AIM:
a) Design RC phaseshift oscillator to have resonant frequency of 6KHz.
Assume R1 = 100k, R2 = 22K, RC = 4 K ,RE =1K & VCC = 12V.
b) Obtain hfe for the above designed value for AV > - 29, R≥ 2 RC.
APPARATUS: Multisim software.
DESIGN PROCEDURE:
a) Let R = 10K
)tan(1962.0104466102
1462
1
dardsSelectnFnFKKKK
C
RR
KWhenKR
f C
Cr
≈=
×+××=∴
=+
=
π
π
nFCKR 1;10 ==∴
1.97
42923)
=
+=≥ noscillatiosustainedforKK
hfeb
CIRCUIT DIAGRAM:
Q2
2N2222A
R1100kohm
R222kohm
R34kohm
R41kohm
12VVCC
C1
10uF
C2
10uF
AB
T G
XSC1
C3100uF
C4
1.0nF
C5
1.0nF
C6
1.0nF
R510kOhm_5%
R610kOhm_5%
R710kOhm_5%
4
6 7
VCC
10
11
0
9
12
PROCEDURE: Rig up the circuit using multisim software and verify the
results using Oscilloscope.
RESULT: RC phase shift oscillator with fr =6KHz is designed. The value of hfe
for the designed value is computed.
TEST YOUR SELF
1. What is an Oscillator circuit?
2. What is the main difference between an amplifier and an oscillator?
3. State Barkhausen criterion for oscillation.
4. State the factors on which oscillators can be classified.
5. Give the expression for the frequency of oscillation and the minimum
gain required for sustained oscillations of the RC phase shift oscillator.
6. Why three RC networks are needed for a phase shift oscillator? Can it be
two or four?
7. What are the merits and demerits of phase shift oscillator?
8. At low frequency which oscillators are found to be more suitable?
9. What are the two important RC oscillators?
10. What makes Quartz produce stable oscillations?
11. What are the factors which contribute to change in frequency in
oscillators?
CLASS A,AB,B,C POWER AMPLIFIERS AIM :
To study the operation of Class A, Class AB, Class B, Class C power amplifiers.
APPARATUS: Multisim soft ware. CIRCUIT DIAGRAM:
R1
100ohm
C147uF
R21kohm
R330kohm
C247uF
R4100ohm
V150mV35.36mV_rms1000Hz0Deg
Q1PN2369A
R51kohm
A BT
G
XSC1
V212V
THEORY: The classification of amplifiers is based on the position of the quiescent point and extent of the characteristics that is being used to determine the method of operation. There are 4 classes of operations.They are
1.Class A 2.Class AB 3.Class B 4.Class C
CLASS A:- In class A operation the quiescent point and the input signal are such that the current in the output circuit (at the collector) flows for all times. Class A amplifier operates essentially over a linear portion of its characteristic there by giving rise to minimum of distortion . CLASS B:- In class B operation , the quiescent point is at an extreme end of the characteristic , so that under quiescent conditions the power drawn from the dc power supply is very small .If the input signal is sinusoidal, amplification takes place for only half cycle. CLASS AB:- A class AB amplifier is the one that operates between the two extremes defined for class A and Class B. Hence the output signal exists for more than 1800 of the input signal. CLASS C :- In class C operation, the quiescent operating point is chosen such that output signal (voltage or current)is zero for more than on half of the input sinusoidal signal cycle. PROCEDURE:
1. An input sine wave (peak-peak)of 50mV is applied to the circuit. 2. connect the output to the C.R.O.
3. varying R3 value, observe and record the output waveforms for different
classes of operation. 4. Also observe the Vi & Vo waveforms using parameter sweep for different
classes of operation.
OBSERVATIONS: CLASS A:
CLASS AB :
CLASS B :
CLASS C :
RESULT :
1. In class A amplifier output current flows for whole 3600
2. In class AB power amplifier output current flows between 1800 and 3600
3. In class B power amplifier output current flows for 1800
4. In Class C power amplifier output current flows for less than 1800.
TRY YOUR SELF
1. How do you bias class A operation?
2. What is conversion efficiency?
3. Define Class B mode of operation.
4. What are the advantages & disadvantages of Class B mode of operation?
5. Distinguish between voltage and power amplifier?
6. Which power amplifier gives minimum distortion?
7. What are the drawbacks of class C amplifier?
8. In Which class of amplifier, the efficiency is high? And why?
9. Classify power amplifiers on the basis of the mode of operation.
10. Give two drawbacks of Class A power amplifier.
HIGH FREQUENCY COMMON BASE AMPLIFIER
AIM - Design a common Base high frequency amplifier with a over all gain of
30 and Lower cut off frequency of 130 Hz and Higher cut frequency 10 MHz .
Transistor Specifications: hib = 22.6, hfb = -0.98, hrb = 2.9×10-4 , hob = 0.49µ s,
IC = 1.35ma = -IE, VCE = 5.85V, VEB = 0.6V, VCB = 5.25V.
Verify the DC values (Voltage and current) at various nodes using Multisim
software
APPARATUS: Multisim software. DESIGN PROCEDURE: 1. DESIGN OF BIASING CIRCUIT : VBE = 0.6V, VCE = 5.85V, IC = 1.35mA = -IE VCB = 5.25V
Find the value of Re : KVL to Input: -2v – Re(1.35ma) + 0.6 = 0 Re =
ma35.14.1 =1.03 KΩ
Find the value of RC : KVL to Output : Vcc – ICRC - VCB = 0 12 – 1.35ma RC – 5.25 = 0 1.35mRc = 6.75 RC = 5kΩ 2.DESIGN OF AMPLIFIER CIRCUIT : 1.To find Cb
Assume Rs = 100Ω Calculate the value of Cb fL =
bCRiRs )(21+π
; 130= bC)6.22100(28.6
1Ω+
Cb =
130)6.22100(28.61+
= 9.9×10-6 ≈10µ f
2.To Calculate RL AV = -hfb
RiRL'
= 0.98× 6.22'RL
Overall gain = AVS = Av RsRi
Ri+
For above circuit Ri 1= Ri=hib
AVS = -hfb RsRi
RL+
' RL
1 = RL 11 RC =3.75k
RL = 15kΩ 3. To Calculate Shunt Capacitance Csh fh =
shCLR ′×′π21
Ω×××=′
kshC
75.3101021
6π
= 4.24 pf ≈4pf The Internal junction capacitance Cb’c ≈3pf C’sh = Cb’c + Csh 4.24 = 2.9pf + Csh Csh = 1.34pf ≈2pf
CIRCUIT DIAGRAM :
Q1
BC107BPRs
100ohm
V1
10mV7.07mV_rms1000Hz0Deg
Re1kohm
Rc5kohm
VCC12V
VEE2V
A BT
G
XSC1
Cb110uFCb 10uF
R515kohm
Csh2pF
8
6
0
7
11 1210 3
PROCEDURE: 1.Rig up the circuit using multisim software and verify the results using DC operating point analysis (Simulate ------Analysis------ DC operating point)
2. Rig up the circuit using multisim software and verify the results using AC
analysis (Simulate--- Analysis--- AC analysis)
RESULTS: The common base high frequency amplifier is designed. Also DC
voltages / currents are observed. The Bandwidth is far greater than the
bandwidth of the CE amplifier.
TEST YOUR SELF
1. What are the factors to be taken into account in the high frequency model of a transistor?
2. What are α and β cut off frequencies? 3. What is unity gain small signal band width? 4. What is the relation between fT & fβ? 5. What is the expression for trans conductance gm in the high frequency
model? 6. What is the expression for input conductance gb′e in terms of gm ? 7. What is base spreading resistance? 8. Give the expressions for the hybrid ∏ capacitances.
RG
15kohm
C1
10uF
R25.1kohm
R133kohm
RC2.2kohm
RE
510ohm
CC
10uF
R315kohm
R42.7kohm
R51kohm
R62.2kohm
CE
10uF
C2
10uF
C3
10uF
Q1BC107BP
Q2BC107BP
12VVCC
TWO STAGE RC COUPLED AMPLIFIER AIM:
1. To study the Two-stage RC coupled amplifier.
2. To measure the voltage gain of the amplifier at 1KHz.
3. To obtain the frequency response characteristic and the band width of the
amplifier.
EQUIPMENT: Two stage RC coupled amplifier, trainer.
1. Signal Generator.
2. C.R.O
3. Connecting patch cords.
CIRCUIT DIAGRAM: OUTPUT INPUT V VO 50mV
PROCEDURE: 1.Switch ON the power supply.
2. Connect the signal generator with sine wave output 50mV p-p at the
input terminals.
3. Connect the C.R.O at output terminals of the module.
4. Measure the voltage at the second stage of amplifier.
5. Now vary the input frequency from 10Hz to 1MHz in steps,and for every
value of input frequency note the output voltage keeping the input
amplitude at constant value.
6. Calculate the gain magnitude of the amplifier using the formula
Gain = Vo/Vi
Gain in dB= 20 log (Vo / Vi )
7. Plot a graph of frequency versus gain (dB) of the amplifier. Sample
frequency response graph is as shown in fig. Below.
OBSERVATION: Vi = 50mV(p-p)
Frequency VO Gain =20 log (Vo/Vi)dB
FREQUENCY RESPONSE:
0.707 VO/VI FL FH Gain VO/VI FL FH Frequency RESULT: The gain of the amplifier at 1 KHz is ------
The BW of the amplifier is -------
CURRENT SHUNT FEEDBACK AMPLIFIER AIM: 1. To study the current shunt feedback amplifier
2. To measure the voltage gain of the amplifier at 1KHz.
3. To obtain the frequency response characteristic and the band width
of the amplifier.
EQUIPMENT: Current shunt feed back amplifier trainer.
4. Signal Generator.
5. C.R.O
6. Connecting patch cords.
CIRCUIT DIAGRAM:
PROCEDURE: 1. Switch ON the power supply.
2. Connect the signal generator with sine wave output 50mV p-p at the
input terminals.
3. Connect the C.R.O at output terminals of the module.
4. Measure the voltage at the second stage of amplifier.
5. Now vary the input frequency from 10Hz to 1MHz in steps, and for
each value of input frequency note the output voltage keeping the
input amplitude at constant value.
6. Calculate the gain magnitude of the amplifier using the formula
Gain = Vo/Vi
Gain in dB= 20 log (Vo / Vi )
7. Plot a graph of frequency versus gain (dB) of the amplifier. Sample
frequency response graph is as shown in fig. Below.
OBSERVATIONS : Vi = 50mV(p-p)
Frequency VO Gain =20 log (Vo/Vi)dB
FREQUENCY RESPONSE:
RESULT: The gain of the amplifier at 1 KHz is ------
The BW of the amplifier is -------
CLASS A/B/C/AB POWER AMPLIFIER AIM: To study the operation of Class A, Class B, Class AB and Class C power
amplifiers.
EQUIPMENT: 1.Class/A/B/C/AB amplifier trainer
2.Function generator.
3.C.R.O
4. Connecting patch cords.
CIRCUIT DIAGRAM:
PROCEDURE:
1.Connect the circuit as shown in the circuit diagram, and get the circuit
verified by your Instructor.
2. Connect the signal generator with sine wave at 1KHz and keep the
amplitude at .5V (peak-to-peak)
3. Connect the C.R.O across the output terminals.
4. Now switch ON the trainer and see that the supply LED glows.
5. Keep the potentiometer at minimum position, observe and record
the waveform from the C.R.O.
6. Slowly varying the potentiometer, observe the outputs for the
Class A/B/AB/C amplifiers as shown in fig.
CLASS A:
CLASS B:
CLASS AB:
CLASS C :
RESULT: It is observed that for class A amplifier, the transistor conducts for
360deg, for class AB more than 180deg and for Class C less than 180 deg.
SINGLE TUNED VOLTAGE AMPLIFIER AIM: 1.To calculate the resonant frequency of tank circuit.
2. To plot the frequency response of the tuned amplifier.
EQUIPMENT:
1. Tuned voltage amplifier trainer.
2. Function generator.
3. C.R.O.
4. Connecting patch cords.
CIRCUIT DIAGRAM:
PROCEDURE: 1.Connect the circuit as shown in fig and get the circuit verified by your Instructor.
2. Connect the signal generator with sine wave at the input and
keep the amplitude to minimum position, and connect a C.R.O at
output terminals of the circuit.
3. Apply the amplitude between 1.6v to 4.4v to get the distortion
less output sine wave.
4. Now, vary the input frequency in steps and observe and record
The output voltage.
5. Calculate the gain of the tuned RF amplifier using the formula
Gain = out put voltage/ input voltage.
6. plot a graph with input frequency versus gain (in dBs)
Gain (in dBs) = 20 log (Vo/Vi)
Graph :-
Gain Frequency RESULT: The tuned amplifier offers maximum gain at resonant frequency of the tank circuit.
50%
SERIES VOLTAGE REGULATOR
AIM : To study and design a Series voltage regulator and to observe the load
regulation feature.
EQUIPMENT :
1. Series voltage regulated power supply trainer.
2. Multimeter.
3. Patch chords.
CIRCUIT DIAGRAM:
3055 + - 560E IL Rs + - IR + Un Regulated - IZ 500E VO Input VZ=12V
PROCEDURE:
1. Switch ON the power supply.
2. Observe the Unregulated voltage at the output of rectifier.
3. Connect this voltage to the input of series voltage regulator circuit.
4. Keep the load resistance 1K at constant.
5. Observe the output voltage VO = VZ-VBE
6. And also observe the voltage across RS,and values of IR,IL and IZ.
7. Compare the practical values with theoretical values.
8. By changing the load resistance, observe the output voltage and various
currents.
OBSERVATIONS:
RL VO IR IZ IL
LOAD REGULATION : VO RL RESULT: The regulator maintains a constant output voltage inspite of the
changes in load conditions.
50%
SHUNT VOLTAGE REGULATOR
AIM : To study and design a Shunt Regulator and to observe the load regulation feature. EQUIPMENT :
1. Shunt regulated power supply trainer.
2. Multimeter.
3. Patch chords.
CIRCUIT DIAGRAM: RS + - + -
220E IL + Un Regulated 8.2V IC 1K
In put - RL VO 3055
PROCEDURE: 1. Switch On the main power supply.
2. Observe the unregulated voltage at the output of rectifier.
3. Connect this voltage to the input of shunt Regulator circuit
4 .Keep the load resistance 1K constant.
5. Observe the output voltage across the load resistor V0 =VZ + VBE
6. Also observe IL, IS & IC.
7. Compare the practical values with theoretical values.
8. By changing the load resistance, observe the output voltage and
various currents.
OBSERVATIONS:
RL VO IS IC IL
LOAD REGULATION: VO RL RESULT: The regulator maintains a constant output voltage inspite of the changes in load conditions.