diode clipping circuits components required
TRANSCRIPT
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EXP-1
DIODE CLIPPING CIRCUITS
Aim: To design and test diode clipping circuits for peak clipping and peak detection.
Components required:
-Power Supply
-Diodes IN4007or BY127
-Resistors
Procedure:
Make the Connections as shown in the circuit diagram
Apply sinusoidal input Vi of 1 KHz and of amplitude 8V P-P to the circuit. Observe the output signal in the CRO and verify it with given waveforms.
Apply Vi and Vo to the X and Y channel of CRO and observe the transfer characteristic waveform and verify it.
I)Positive Clipping
Circuit: Circuit
Diagram:
R
8Vp-p
Waveforms:
3.3KD
Vi VoVR 2.4
V
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Dept of E&C, CEC Analog Electronics Lab Manual
Transfer Characteristics:
To find the aluee of R:
Given: Rf =100Ω, Rr =100KΩ
Rf - Diode forward
resistance Rr - Diode
reverse resistance
R= =3.16KΩ
Choose R as 10 KΩ
Let the output voltage be clipped at
+3V Vomax =3V
From the circuit diagram,
Vomax = Vr+Vref
Where Vr is the diode drop =
0.6V Vref = Vomax -Vr
=3 - 0.7
Vref = 2.3 V
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3.3K
BY127
Vi Vo
VR 2.4V
Dept of E&C, CEC Analog Electronics Lab Manual
II)Negative Clipping
Circuit: Circuit
Diagram:
R
Waveforms:
Trlnsfe r Chlrlcte ristcs:
Let the output voltage be clipped at
-3V Vomin = -3V
Vomin = -Vr+Vref
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Vref = Vomin+Vr = -3 + 0.7
Vref = -2.3V
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EXP-2
CLAMPING CIRCUITS
Aim: Design and test positive and negative clamping circuit for a given reference voltage.
Components required:
- Power Supply
- CRO- Signal Generator- Diode BY 127- Resistors- Capacitor
Design:
Rf – Diode forward resistance =
100Ω Rr – Diode Reverse
resistance = 1M Ω R = =
10KΩ
let T = 1ms
f(1KHz) Let RC =
10T
RC = 10ms
C = 1µF
R =
10KΩ
I) Positive Clamping
Circuits: Circuit
Diagram:
C
+ -
1mF
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8Vp-p Vi
D BY127 R 10K Vo
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Dept of E&C, CEC Analog Electronics Lab Manual
Waveforms:
II) Design a Clamping Circuit to Clamp Negative Peak at +3V:
C
+ -
1mF
8Vp-p Vi
D
R 10K Vo
Vref 3.6V
Waveforms:
Vo = +
Vref 3 = -0.7
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+ Vref
Vref = 3.7
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Dept of E&C, CEC Analog Electronics Lab Manual
III) Negative Clamping
Circuit: Circuit
Diagram:
C
+ -
1mF
8Vp-p Vi
D R 10K Vo
Waveforms:
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EXP-3
Dept of E&C, CEC Analog Electronics Lab Manual
RECTIFIER CIRCUITS
Aim: To design and test Half wave, Full wave, Bridge Rectifer circuits with & without capacitor flter and determine the Ripple factor, Regulation & Efciency.
Components required:
- Resistors- Diodes- 12-0-12V Transformer- Capacitor
Calculations:
Assume RL = 4.7KΩ, C = 220µF
I) Half wave Rectifier:
1. Ripple Factor without Filter (Theoretical) = 1.21
2. Percentage Regulation = (Rf = Diode forward resistance)
3. Rectifer Efciency η = 40.6 %
4. Ripple Factor without Filter = (f = frequency = 50Hz)
II) Full wave Rectifier:
1. Ripple Factor without Filter = 0.48
2. Percentage Regulation = 3. Rectifer Efciency η = 81 %
4. Ripple Factor without Filter =
III) Bridge Rectifier:
1. Ripple Factor without Filter = 0.48
2. Percentage Regulation = 3. Rectifer Efciency η = 81 %
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I)Half wave Rectifier without
Filter: Circuit Diagram:
230V 12V
IN 4001
230V/50Hz
AC
RL=4.7K Vo
0 0
Waveforms:
Peak output voltage
Vm= Vdc = =
Vrms = =
Vac = =
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Ripple Factor =
Rectier efciency η = = = % Regulaton =
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Dept of E&C, CEC Analog Electronics Lab Manual
Half wave Rectier with Filter:
230V 12V
IN 4001
230V/50Hz
AC
+ 220mF
-
RL=4.7K Vo
0 0
Waveforms:
Peak output Voltage
Vm = Ripple Factor =
=
Vdc = =
Vac = =
Vrms = =
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Rectifer efciency η = = 2=
% Regulation =
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Dept of E&C, CEC Analog Electronics Lab Manual
II) Full wave Rectifier without
Filter: Circuit Diagram:
D1
12V
230V/50Hz
AC
RL
4.7K
Vo
12V
D2
Waveforms:
(ms)
Vdc = =
Vrms = =
Vac = =
=
T/2 T 3T/2
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η = = 2=
% Regulation =
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(ms)
T/2 TT
3T/2
T/2
Dept of E&C, CEC Analog Electronics Lab Manual
III) Full wave Rectifier with
Filter: Circuit Diagram:
D1
12V RL
4.7K
C
220m
F
230V/50Hz AC Vo
12V
D2
Waveforms:
Vdc = =
Vac = = Vrms = =
η = = 2=
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Dept of E&C, CEC Analog Electronics Lab Manual
Bridge Rectier without Filter: Circuit Diagram:
230V 12V
230V/50Hz AC
RL
Vo
0
Waveforms:
(ms)
Vdc = =
Vrms = =
Vac = =
=
η = = 2=
D1
D3
D4
D20
T/2 T 3T/2
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% Regulation =
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(ms)
T/2 TT 3T/2
T/2
Bridge Rectifier with
Filter: Circuit Diagram:
230V 12V
230V/50Hz AC
RL Vo
Waveforms:
Vdc = =
Vac = =
=
Vrms = =
η = = 2=
D1 D3D4 D2 +
-0 0 220m
F
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Dept of E&C, CEC Analog Electronics Lab Manual
Procedure:
Make the Connections as shown in the circuit diagram
Apply 230V AC supply from the power mains to the primary of the transformer
Observe the voltage across secondary to get Vm , the peak value in CRO Use relevant formula to fnd Vdc and Vrms of both Full wave and Half wave
rectifer & draw the waveforms
Find out the Ripple factor, Regulation and Efciency by using the formula.
Conclusions:
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EXP-4
R.C.PHASE SHIFT OSCILLATOR
Aim: To design and test the RC Phase shift Oscillator for the frequency of 1KHz.
Components required:
-Transistor (BC 107)
- Resistors- CRO
- Capacitors
Design:
VCC =
12V IC =
2mA
VRC = 40% VCC =
4.8V VRE = 10%
VCC = 1.2V VCE =
50% VCC = 6V
To find RC, R1, RE &R2
We Have,
VRC =
ICRC=4.8V RC
= 2.4KΩ
Choose RC = 2.2KΩ
VRE =
IERE=1.2V RE
= 600Ω
Choose RE = 680Ω
hfe = 100 (For BC
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107) IB= =
20mA
Assume current through R1 = 10 IB & through R2 = 9 IB VR1 = VCC-VR2
= 10V
Also, VR1 =10 IB R1=10.1V
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Dept of E&C, CEC Analog Electronics Lab Manual 10ESL37
R1= 50KΩ
Choose R1= 47KΩ
VR2 = VBE+VRE
= 0.7+1.2
= 1.9V
Also, VR2 =9 IB
R2=1.9V R2=
10.6KΩ
Choose R1= 12KΩ
To find CC & CE
XCE = = = 68Ω
For =
20Hz CE=
117
Choose CE = 220
XCC = = 220Ω
For = 20Hz
Choose CC =
47
Design of Selective Circuit:
Required of oscillations f = 1KHz
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Take R= 4.7KΩ & C=0.01µF
Procedure:
Rig up the circuit as shown in the fgure
Observe the sinusoidal output voltage.
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Vcc = 12V
R1 47KRc2.2K
C C C
Cin0.01mF
0.01mF
0.01mFBC 107
47mF
VoR
R2 12KCE 4.7K
R
4.7K
R
4.7KRE 68
0
220mF
Dept of E&C, CEC Analog Electronics Lab Manual 10ESL37
Measure the frequency and compare with the theoretical values.
Circuit Diagram:
Re seut:
Frequency
Theoretical: 1KHz
Practical:
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1.5KΩ
SL100R11µF1µ
FSK100
1.5KΩ
EXP-5
CLASS ‘B’ PUSH-PULL AMPLIFIER
Aim: To design and test the performance of transformer less Class ‘B’ Push-Pull Amplifer and to determine its conversion efciency.
Components Required:
- Diodes IN 4001
- Transistor SL100, SK100
- Resistors- Capacitors
Circuit Diagram:
Vcc = 15V
Vi RL 470ΩVo
Design:
Given VCC = 15V, RL = 470Ω
VCE1 = VCE2 = =
7.5V
VB1 = VCE2 + VBE1 = 7.5 + 0.7 = 8.2V
Assume I1 = 5mA
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R1 =
= 1.36KΩ
R2 =
=
1.36KΩ
ChooseR1
= R2
= 1.5KΩ
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Dept of E&C, CEC Analog Electronics Lab Manual
Choose Ci = C2 = 1µF
Pi(dc) = VCC Idc
Po(ac) =
Efciency η =
Procedure:
Connect the circuit as shown in the circuit diagram.
Apply the input voltage Vi = 5V
Keeping the voltage constant, vary the frequency from 100Hz to 1MHz in regular steps and note down the output voltage in each case.
Plot the gain Vs Frequency graph.
Note down the dc current Idc
Calculate the efciency.
Observations:
Vi = 5V
Freq. in Hz Vo Gain= Gain in dB
= 20 log
50 Hz100 Hz200 Hz
500 Hz1KHz2KHz
3KHz5 KHz
10 KHz...
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. 1MHz2 MHz
Result:
Efciency η =
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EXP-6
AIM: To check the following applications of OP-AMP.
a) Inverting Amplifer. b) Non inverting amplifer.APPARATUS:
S.No
Name
Range / Value Quantity
1. Fixed power supply [- 15V – 0V – +15V] 1
2. OP-AMP A741C 13. Resistors 1K, 4.7K, 10K,
33KEach 1
4. Function generator -- 1
5. CRO -- 1
PROCEDURE:
INVERTING & NON - INVERTING AMPLIFIER:
1.Connect the circuit as shown in the fgure -1
2.Switch on the power supply and signal generator.
3.Apply a sinusoidal signal with peak to peak amplitude of 20mVat a frequency of 1KHz.
4.Note down the amplitude of O/P signal in the C.R.O.
5.Repeat the above steps for diferent values of Rf.
6.Repeat the above steps for the circuit of fg –2.
7.Tabulate the readings.
CIRCUIT DIAGRAM:
Inae rtng Ampuifie r: Non - inae rtng Ampuifie r:
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INVERTING AMPLIFIER:
Vi = 20mV
S.NO
Rf
( )R1(
) V0 (mV) Gain = V0 / Vi
Theoretical Gain = (-Rf/R1)
1 4.7K 1K
2 10K 1K
3 33K 1K
NON-INVERTING AMPLIFIER:
Vi = 20mV
S.NO
Rf
( )R1(
)V0 (mV)
Gain= V0 / Vi
Theoretical Gain = (1+Rf/R1)
1 4.7K 1K2 10K 1K3 33K 1K
RESULT-
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EXP-7
COLPITTS OSCILLATOR
AIM: To determine the frequency of oscillations of a given Colpitts Oscillator.
APPARATUS:
S.No
Name
Range / Value
Quantity
1. DC Regulated Power Supply (0-30V) 12. Resistors 560, 47 K Each 1
4. Resistors 4.7 K 2
5. Capacitors 100F, 0.047F Each 1
6. Decade Inductance Box -- 1
7. Decade Capacitance Box -- 2
8. CRO -- 1
PROCEDURE:
1. Connect the circuit diagram as shown in the fgure.
2. Switch on the power supply.
3. Connect the out put terminals to CRO.
4. Adjust the capacitances until a sinusoidal wave form is observed on the CRO.
5. Measure the time period of the sinusoidal wave form (T) and determine the Frequency (1/T).
6. Repeat the above steps for diferent values of L, C1 & C2.
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2 LCeq
7. Tabulate the readings and compare with theoretical values
CIRCUIT DIAGRAM
TABULAR FORM:
S.NO.
L (mH)
C (F)
Practical
frequency (Hz)
Theoretical
Frequency (Hz)C1 C2
1
2
3
CALCULATIONS:
f0 (practical) =1/T Hz.
f0 (theoretical)
f 1
. [Where
C
C1 C2 ]0
eq
C1 C2
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38EXP-8
WEIN BRIDGE OSCILLATOR
AIM: To determine the frequency of oscillations of a given Wein Bridge oscillator and compare it with the theoretical value.
APPARATUS:
S.No
Name
Range / Value Quantity
1. Fixed Power Supply [- 15V – 0V – +15V] 12. OP-AMP A741C 1
3. Potentiometer 47 K 1
4. Resistors 3.3 K , 220 Each 2
5. Resistors 12 K 1
6. Capacitors 0.047 F, 0.33 F Each 2
7. CRO. -- 1
PROCEDURE:
1.Connect the circuit as shown in the fgure.
2.Connect 0.047 F, and 3.3 K in place of C and R.
3.Connect the O/P to the C.R.O and observe the sinusoidal signal and measure its frequency.
4.Connect 0.33 F, and 220 in places of C and R.
5.Observe the sinusoidal signal and measure its frequency.
6.Tabulate the readings and Compare it with theoretical values
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39CIRCUIT DIAGRAM:
TABULAR FORM:
S.NoCapacitan
ce C ( F )
Resistance R (Ω)
Theoretical
Frequency =1/2 RC (Hz)
PracticalFrequency=
1/T (Hz)
1
2
0.047
0.33
3.3K
220
FORMULAS:
Practical Frequency =Fо=1/T
Theoretical Frequency=1/2ΠRC
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40
EXP-9
HARTLEY OSCILLATOR
AIM: To Determine the frequency of oscillations of a
Hartley Oscillator and compare it with the theoretical
values.
APPARATUS:
S.No
Name
Range / Value
Quantity
1. D.C Regulated Power Supply
(0 – 30V) 1
2. Resistors 1KΩ, 10kΩ, 47KΩ Each 1
3. Capacitors 0.22µF 2
4. Decade Capacitance Box -- 1
5. Decade Inductance Box -- 2
6. CRO -- 1
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41
PROCEDURE:
1.Connect the circuit as shown in the fgure.
2.Connect the O / P of the oscillator to the C.R.O.
3.Adjust the Capacitance and Inductance Boxes until a
sinusoidal signal is observed in the CRO.
4.Determine the frequency of the wave form.
5.Determine the frequency by varying the capacitance in convenientsteps.
6.Tabulate the readings and compare the readings with the theoretical values.
CKT DIA.
TABULAR FORM:
Capacitance C ( F )
Inductance
( m H )Practical
Frequency (Hz)
Theoretical Frequency (Hz)
L 1 L 2
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42
FORMULAS:
Theoretical Frequency f0 ΠLC
Practcal Frequency F =1/T