Inverting amplifier: [Closed Loop...
Transcript of Inverting amplifier: [Closed Loop...
LINEAR INTEGRATED CIRCUITS LAB
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Inverting amplifier: [Closed Loop Configuration] Design:
ACL = Vo/Vin = - Rf / Rin; Assume Rin = ______; Gain = _______; Circuit Diagram:
Model Graph
Observation:
For input: Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For output: Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
CRO
+
~
+
–
–
+10V
7
6
4
v0
-10V
RF
IC741
2
3
Rin
F.G
(V)
Vin
Vo
(V)
t(sec)
t(sec)
Inverting amp
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EX. NO: 1 DATE: _ _ /_ _ / 2010
Inverting, Non inverting and differential amplifiers.
AIM
To design Inverting, Non inverting amplifier & Differentiator using op-amp and
test its performance
APPARATUS REQUIRED
S.No Components Range Quantity
1. Op-amp IC 741 1
2. Dual trace supply (0-30) V 1
3. Function Generator (0-1) MHz 2
4. Resistors
5. Capacitors
6 CRO (0-30)
MHz
1
THEORY
INVERTING AMPLIFIER
The inverting amplifier is the most widely used of all the op-amp circuits. The
output voltage V0 is fed back to the inverting input terminal through the Rf-R1
network where Rf is the feedback resistor. Input signal Vi is applied to the inverting
input terminal through R1 and non-inverting input terminal of op-amp is grounded.
V0 = - (Rf/R1) Vi
ACL= V0/Vi = -Rf/R1
The negative sign indicates a phase shift of 1800 between Vi and V0.
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NON-INVERTING AMPLIFIER
The non-inverting amplifier circuit amplifies without inverting the input
signal. In this circuit, the input is applied the non-inverting input terminal &
inverting input terminal is grounded. Such a circuit is called non-inverting
amplifier. It is also a negative feedback system as output is being fed back to the
inverting input terminal.
Vo = ( 1 + Rf/R1) Vi
ACL=Vo/Vi = 1 + Rf/R1
Non inverting amplifier Design
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Non inverting amplifier: [Closed Loop Configuration]
Design:
ACL = Vo / Vin = 1 + Rf / Rin; Assume Rin = ______; Gain = _______;
Circuit Diagram
Model Graph
Observation:
For input: Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For output: Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
(V)
Vin
Vo
(V)
t(sec)
t(sec)
Non-Inverting amp
CRO
+
~
+
–
–
+10V
7
6
4
v0
-10V
2
3
Rin
F.G
RF
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DIFFERNTIAL AMPLIFIER
The differential amplifier has a unique feature that many circuits don’t have -
two inputs. This circuit amplifies the difference between its input terminals. Many
circuits that have one input, actually have another input – the ground potential. The
differential amp rejects the noise common to both signals and rescues the signal
difference between the input terminals.
Design of Differential amplifier
R1=R2=R3=Rf = R = __________
VO = Rf / R [V2 – V1]
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Circuit Diagram
Observation:
For input 1: Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For input 2: Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
For output: Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
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Procedure:
1. Connect the components as per the circuit diagram.
2. Set the input voltage using F.G
3. observe the output waveform at Pin no.6
4. Connect CRO at Pin no.6 and measure 0/p voltage and note it down.
5. Plot the output waveforms
RESULT:
Pre – Lab Test (20) Remarks &
Signature
with Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
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Circuit Diagram
Model Graph:
Observation:
For sine wave input:
Peak to peak amplitude of the input = volts. Frequency of the input = Hz Peak to peak amplitude of the output = volts. Frequency of the output = Hz
For square wave input: Peak to peak amplitude of the input = volts. Frequency of the input = Hz Peak to peak amplitude of the output = volts. Frequency of the output = Hz
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EX. NO: 2 DATE: _ _ /_ _ / 2010
INTEGRATOR AND DIFFERENTIATOR
AIM
To design an integrator & Differentiator using op-amp and test its performance.
APPARATUS REQUIRED
S.No Components Range Quantity
1. Op-amp IC 741 1
2. Dual trace supply (0-30) V 1
3. Function Generator (0-1) MHz 1
4. Resistors
5. Capacitors
6 CRO (0-30)
MHz
1
DIFFERENTIATOR:
A circuit in which output waveform is the derivative of the input waveform is known
as the differentiator or the differentiation amplifier. Such a circuit is obtained by using
operational amplifier in the inverting configuration connecting a capacitor, C1 at the
input V0= - RfC1 dVi/dt
INTEGRATOR:
The circuit performs the mathematical operation of Integration, that is, the
output waveform is the integral of input waveform.
V0 (t)= -1/R1Cf ∫Vi(t)dt+V0(0)
V0 (0) = initial output voltage
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Differentiator:
Design:
Step1: Select fa equal to the highest frequency of the input signal to be
differentiated. Then assuming a value of C1 < 1µF. calculate the value of Rf.
Step2: Choose fb = 20 fa and calculate the values of R1 and Cf so that R1C1 = Rf Cf.
fa = KHz ; fb = KHz ;C1 = 0.1 µf; RCOMP = Rf ; RL = 10KΩ
fa = 1/ [2πRfC1]; Rf = 1/2π C1 fa ; fb = 1/ [2πR1C1];R1 = 1/2π C1 fb;R1C1 = Rf Cf;
Cf = R1C1/ Rf
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Integrator:
Design:
Generally the value of the fa and in turn R1Cf and Rf Cf values should be selected
such that fa < fb. From the frequency response we can observe that fa is the frequency
at which the gain is 0 db and fb is the frequency at which the gain is limited. Maximum
input signal frequency = 1 KHz.
Condition is time period of the input signal is larger than or equal to Rf Cf (i.e.)
T 1 fR C≥
fb = KHz ; fa = fb/10; Rf = 10R1; RCOMP = R1; RL & R1 = 10KΩ
fa = 1/ [2πRfCf]; Rf Cf = 1msec &; Cf = 1msec/100K
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Circuit Diagram:
Model Graph
Observation:
For sine wave input:
Peak to peak amplitude of the input = volts.
Frequency of the input = Hz
Peak to peak amplitude of the output = volts.
Frequency of the output = Hz
For square wave input:
Peak to peak amplitude of the input = volts.
Frequency of the input = Hz
Peak to peak amplitude of the output = volts.
Frequency of the output = Hz
Vin
RL
R1
+12V
-12V
Rf
Cf
Rom = R1
+
-
IC 7413
26
74
0
VO = - [1/R1Cf] ∫Vin dt
RCOMP
Vin
Vo
t
t
Model graph
t
t
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Procedure:
1. Connect the components as per the circuit diagram.
2. Set the input voltage using F.G
3. observe the output waveform at Pin no.6
4. Connect CRO at Pin no.6 and measure 0/p voltage and note it down.
5. Plot the output waveforms
RESULT:
Pre – Lab Test (20) Remarks &
Signature
with Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
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EX. NO: 3 DATE: _ _ /_ _ / 2010
INSTRUMENTATION AMPLIFIER
AIM
To design an instrumentation amplifier Using Op-Amp & test its performance.
APPARATUS REQUIRED
S.No Components Range Quantity
1. Op-amp IC 741 3
2. Dual trace supply (0-30) V 1
3. Function Generator (0-1) MHz 2
4. Resistors
5. Capacitors
6 CRO (0-30)
MHz
1
THEORY
INSTRUMENTATION AMPLIFIER:
An instrumentation (or instrumentational) amplifier is a type of differential
amplifier that has been outfitted with input buffers, which eliminate the need for input
impedance matching and thus make the amplifier particularly suitable for use in
measurement and test equipment. Additional characteristics include very low DC
offset, low drift, low noise, very high open-loop gain, very high common-mode
rejection ratio, and very high input impedances. Instrumentation amplifiers are used
where great accuracy and stability of the circuit both short- and long-term are
required.
The electronic instrumentation amp is almost always internally composed of 3 op-
amps. These are arranged so that there is one op-amp to buffer each input (+,−), and
one to produce the desired output with adequate impedance matching for the
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function.Consider all resistors to be of equal value except for Rgain. The negative
feedback of the upper-left op-amp causes the voltage at point 1 (top of Rgain) to be
equal to V1. Likewise, the voltage at point 2 (bottom of Rgain) is held to a value equal to
V2. This establishes a voltage drop across Rgain equal to the voltage difference between
V1 and V2. That voltage drop causes a current through Rgain, and since the feedback
loops of the two input op-amps draw no current, that same amount of current through
Rgain must be going through the two "R" resistors above and below it. This produces a
voltage drop between points 3 and 4 equal to:
The regular differential amplifier on the right-hand side of the circuit then takes this
voltage drop between points 3 and 4, and amplifies it by a gain of 1 (assuming again
that all "R" resistors are of equal value). Though this looks like a cumbersome way to
build a differential amplifier, it has the distinct advantages of possessing extremely
high input impedances on the V1 and V2 inputs (because they connect straight into the
noninverting inputs of their respective op-amps), and adjustable gain that can be set
by a single resistor. Manipulating the above formula a bit, we have a general
expression for overall voltage gain in the instrumentation amplifier:
Though it may not be obvious by looking at the schematic, we can change the
differential gain of the instrumentation amplifier simply by changing the value of one
resistor: Rgain. The overall gain can be changed by changing the values of some of the
other resistors, but this would necessitate balanced resistor value changes for the
circuit to remain symmetrical. Please note that the lowest gain possible with the above
circuit is obtained with Rgain completely open (infinite resistance), and that gain value
is 1.
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Circuit Diagram
Observation
For input 1: Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For input 2: Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For output: Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
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Instrumentation amplifier Design:
, R=________, Rgain=___________-
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Procedure:
1. Connect the components as per the circuit diagram.
2. Set the input voltage using F.G .
3. observe the output waveform at Pin no.6
4. Connect CRO at Pin no.6 and measure 0/p voltage and note it down.
5. Plot the output waveforms
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RESULT:
Contents Marks obtained Signature Prelab test(20) Postlab test(20) Simulation(25) Circuit connection and result(35)
Total
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EX. NO: 4 DATE: _ _ /_ _ / 2010
ACTIVE LOWPASS, HIGHPASS AND BANDPASS FILTERS.
AIM
To design an active low pass, high pass and band pass filter Using Op-Amp &
test its performance.
APPARATUS REQUIRED
S.No Components Range Quantity 1. Op-amp IC 741 1 2. Resistors 3. Capacitor O.01µf 2 4. CRO 1 5. Power Supply ± 15V 1 6. Probe 2 7. Bread Board 1
Thoery
LPF: A LPF allows only low frequency signals up to a certain break-point fH to pass
through, while suppressing high frequency components. The range of frequency
from 0 to higher cut off frequency fH is called pass band and the range of frequencies
beyond fH is called stop band.
Design Procedure:
1. Choose the cutoff frequency wc or fc
2. Pick c1, choose value <=0.1 µF
3. Make C2=2C1
4. Calculate R=0.707/wcC1
5. Choose Rf=2R
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LPF Design:
Procedure:
LPF:
1. Connections are given as per the circuit diagram.
2. Input signal is connected to the circuit from the signal generator.
3. The input and output signals of the filter channels 1 and 2 of the CRO are
connected.
4. Suitable voltage sensitivity and time-base on CRO is selected.
5. The correct polarity is checked.
6. The above steps are repeated for second order filter
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Tabulation Second order LPF Vin= S.No Frequency (Hz) O/p voltage(v) Gain=Vo/Vin Gain=20log(Vo/Vin)
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HPF:
A high-pass filter, or HPF, is an LTI filter that passes high frequencies well but
attenuates (i.e., reduces the amplitude of) frequencies lower than the filter's cutoff
frequency. The actual amount of attenuation for each frequency is a design parameter
of the filter. It is sometimes called a low-cut filter or bass-cut filter.
Design Procedure:
1.Choose a cutoff frequency wc or fc.
2. Let C1=C2=C and choose a convenient value.
3. Calculate R1 from R1=1.414/wcC
4. Select R2=(1/2)R1
5 . To minimize dc offset , let Rf=R1
Design of HPF
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Tabulation Second order HPF Vin=
Procedure:
1. Connections are given as per the circuit diagram.
2. Input signal is connected to the circuit from the signal generator.
3. The input and output signals of the filter channels 1 and 2 of the CRO are
connected.
4. Suitable voltage sensitivity and time-base on CRO is selected.
5. The correct polarity is checked.
6. The above steps are repeated for second order filter.
S.No Frequency (Hz) O/p voltage(v) Gain=Vo/Vin Gain=20log(Vo/Vin)
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BPF:
A band-pass filter is a device that passes frequencies within a certain range and
rejects (attenuates) frequencies outside that range.
BPF Design:
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Tabulation:- BPF Vin= S.No Frequency (Hz) Vo(volts) Gain=20log(Vo/Vin)
Procedure:
BPF:-
1. The input signal is connected to the circuit from the signal generator.
2. The input and output signals are connected to the filter.
3. The suitable voltage is selected.
4. The correct polarity is checked.
5. The steps are repeated.
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RESULT:
Contents Marks obtained Signature Prelab test(20) Postlab test(20) Simulation(25) Circuit connection and result(35)
Total
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Circuit Diagram
Observation
Output:
Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
.
2
+10V
IC741
R
+
CRO
C
3
–10V
10KΩΩΩΩ
R1
R2
11.6ΩΩΩΩ
VO4
7–
6
10 kΩΩΩΩ
0.05µf
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Ex. No 5 DATE: _ _ /_ _ / 2010
Astable ,Monostable Multivibrators and Schmitt trigger using op-amp
Aim
To design Astable, monostable Multivibrators and Schmitt trigger using op-
amp and plot its waveforms.
Apparatus Required:
S.No Component Range Quantity
1. Op amp IC 741 1
2. DTS (0-30) V 1
3. CRO 1
4. Resistor 1
5. Capacitors – –
6. Diode IN4001 2
7. Probes – 1
THEORY:
ASTABLE MULTIVIBRATOR:
Multivibrators are a group of regenerative circuits that are used extensively in
timing applications. It is a wave shaping circuit which gives symmetric or asymmetric
square output. It has two states either stable or quasi- stable depending on the type of
multivibrator.
Astable multivibrator is a free running oscillator having two quasi-stable states.
Thus, there is oscillations between these two states and no external s i g n a l a r e
required to produce the change in state.
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Astable Multivibrator:
Design:
T = 2RC
R1= 1.16 R2
Given fo = _______KHz
Frequency of Oscillation fo = 1 / 2 RC if R1 = 1.16R2
Let R2 = 10 K
R1 = 10
Let C = 0.05 F
R = 1 / 2 fC = 1/ (2
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MONOSTABLE MULTIVIBRATOR:
Monostable multivibrator is one, which generates a single pulse of specified
duration in response to each external trigger signal. It has only one stable state.
Application of a trigger causes a change to the quasi-stable state. An external trigger
signal generated due to charging and discharging of the capacitor produces the
transition to the original stable state
Design:
Monostable Multivibrators:
β = R2/R1+R2 [ = 0.5 & R1 = 10 K]
Find R2 = ; R3 = 1K; R4 = 10K;
Let F =_____KHz ; C= 1mfd; C4 = 0.1mfd
Pulse width, T = 0.69RC
Find R =
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Circuit Diagram
Model graph:
CRO
+
–
+10V
7
4
-10V
2
3
IC741
R
Vββββsat
C4 D2
R4
D1C
VC
6R3
VO
R1
R2
Vin
Vin
VC
VO
Vsat
Vββββsat
VD
t
t
t
T–V sat
TP
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Observation
Input:
Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
Output:
Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
Procedure:
Astable multivibrator
1. Make the connections as shown in the circuit diagram
2. Keep the CRO channel switch in ground and adjust the horizontal line on the x
axis so that it coincides with the central line.
3. Select the suitable voltage sensitivity and time base on the CRO.
4. Check for the correct polarity of the supply voltage to op-amp and switch on
power supply to the circuit.
5. Observe the waveform at the output and across the capacitor. Measure the
frequency of oscillation and the amplitude. Compare with the designed value.
6. Plot the Waveform on the graph.
Monostable Multivibrator:
1. Make the connections as shown in circuit diagram.
2. A trigger pulse is given through differentiator circuit through pin no.3
3. Observe the pulse waveform at pin no.6 using CRO and note down the time
period.
4. Plot the waveform on the graph.
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Circuit Diagram
Model Graph
Vin
+12V
R1
-12V
R2
0
+
-
3
26
74
RL = 10K
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SCHMITT TRIGGER:
If the input to a comparator contains noise, the output may be erractive when
vin is near a trip point. For instance, with a zero crossing, the output is low when vin is
positive and high when vin is negative. If the input contains a noise voltage with a peak
of 1mV or more, then the comparator will detect the zero crossing produced by the
noise.
This can be avoided by using a Schmitt trigger, circuit which is basically a
comparator with positive feedback.
Because of the voltage divider circuit, there is a positive feedback voltage.
When OPAMP is positively saturated, a positive voltage is feedback to the non-
inverting input; this positive voltage holds the output in high stage. (vin< vf). When the
output voltage is negatively saturated, a negative voltage feedback to the inverting
input, holding the output in low state.
Schmitt Trigger:
Design
VCC = 12 V; VSAT = 0.9 VCC; R1= 47KΩ; R2 = 120Ω
VUT = + [VSAT R2] / [R1+R2] & VLT = - [VSAT R2] / [R1+R2] &
HYSTERESIS [H] = VUT - VLT
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Observation:
For sine wave input:
Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For square wave input:
Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
Upper Threshold voltage , VUT =
Lower Threshold voltage , VLT =
Hysteresis voltage, VH =
Procedure
1. Connect the circuit as shown in the circuit
2. Set the input voltage as 5V (p-p) at 1KHz. (Input should be always less than Vcc)
3. Note down the output voltage at CRO
4. To observe the phase difference between the input and the output, set the CRO
in dual Mode and switch the trigger source in CRO to CHI.
5. Plot the input and output waveforms on the graph.
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RESULT:
Pre – Lab Test (20) Remarks &
Signature
with Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
LINEAR INTEGRATED CIRCUITS LAB
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Wein Bridge Oscillator:- Circuit Diagram:-
CRO
+
–
+10V
7
6
4
-10V
2
3
ICY41
R1=10 kΩΩΩΩ Rf =20 kΩΩΩΩ
3.2kΩΩΩΩR
C0.05 µµµµf
3.2kΩΩΩΩR = C 0.05µµµµf
VO
Model Graph:
t
+ Vp
V O
–Vp
Observation: Peak to peak amplitude of the output = volts.
Frequency of oscillation = Hz.
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EXP.NO.6:- DATE: _ _ /_ _ / 2010
Phase shift and Wien bridge oscillators Aim:
To design the following sine wave oscillators
a) Wein Bridge Oscillator with the frequency of 1 KHz.
b) RC Phase shift oscillator with the frequency of 200 Hz.
Components Required:
S.No Components Range Quantity
1. Op-amp IC 741 1
2. Dual trace supply (0-30) V 1
3. Function Generator (0-2) MHz 1
4. Resistors
5. Capacitors
6 CRO (0-30) MHz 1
7 Probes -- --
THEORY:
WEIN BRIDGE OSCILLATOR:
A Wien bridge oscillator is a type of electronic oscillator that generates sine
waves. The bridge comprises four resistors and two capacitors. It can generate a large
range of frequencies. The frequency of oscillation is given by:
F = 1/2 RC
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Circuit Diagram:-
CRO
+
–
+10V
7
6
4
-10V
2
3
IC741
R1 1 mΩΩΩΩ
3.3kΩΩΩΩ
C
VO 0.01µµµµf
CC
RRR 3.3kΩΩΩΩ3.3kΩΩΩΩ
0.01µµµµf 0.01µµµµf
32kΩΩΩΩ
33kΩΩΩΩ Rf
DRB
Model Graph: VO
t
Observation:
Peak to peak amplitude of the sine wave = Volts
Frequency of Oscillation (obtained) = Hz.
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RC Phase Shift Oscillators: Design:
Frequency of oscillation fo = 1/(√6*2*Π*RC)
Av = [Rf/R1] = 29
R1 = 10 R
Rf = 29 R1
Given fo = 200 Hz.
Let C = 0.1µF
( )( )6
R 1 / 6 * 2 * fo * C
1 / 6 * 2 * * 200 * 0.1 *10
K
To prevent the loading of amplifier by RC network, R1 10R
R1 10 * K
Since Rf 29R1
Rf 29 *
M
−
= π
= π
= Ω
≥
∴ = − − − − − − = Ω
=
= − − − − − −
= Ω
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RC PHASE SHIFT OSCILLATOR:
A phase-shift oscillator is a simple sine wave electronic oscillator. It contains
an inverting amplifier, and a feedback filter consisting of an RC network which 'shifts'
the phase by 180 degrees at the oscillation frequency.
The filter must be designed so that at frequencies above and below the
oscillation frequency the signal is shifted by either more or less than 180 degrees. This
results in constructive superposition for signals at the oscillation frequencies, and
destructive superposition for all other frequencies
The most common way of achieving this kind of filter is using three cascaded
resistor-capacitor filters, which produce no phase shift at one end of the frequency
scale, and a phase shift of 270 degrees at the other end. At the oscillation frequency
each filter produces a phase shift of 60 degrees and the whole filter circuit produces a
phase shift of 180 degrees. The mathematics for calculating the oscillation frequency
and oscillation criterion for this circuit are surprisingly complex, due to each R-C stage
loading the previous ones.
Equations Related to the Experiments:
a) Wein Bridge Oscillator Closed loop gain Av = (1+Rf/R1) = 3 Frequency of Oscillation fa = 1/(2πRC)
b) RC Phase shift Oscillator: Gain Av = [Rf/R1] = 29
Frequency of oscillation fa = 1 6 * 2 * * RCπ
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Wein Bridge Oscillator: Design: Gain required for sustained oscillation is Av = 1/β = 3
(PASS BAND GAIN) (i.e.) 1+Rf/R1 = 3
∴ Rf = 2R1
Frequency of Oscillation fo = 1/2π R C
Given fo = 1 KHz
Let C = 0.05 µF
∴ R = 1/2 π foC
R = 3.2 KΩ
Let R1 = 10 KΩ ∴ Rf = 2 * 10 KΩ
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Procedure:
Wein Bridge Oscillator
1. Connect the components as shown in the circuit.
2. Switch on the power supply and CRO.
3. Note down the output voltage at CRO.
4. Plot the output waveform on the graph.
5. Redesign the circuit to generate the sine wave of frequency 2 KHz.
6. Compare the output with the theoretical value of oscillation.
RC Phase shift Oscillator
1. Connect the circuits as shown in the circuit
2. Switch on the power supply.
3. Note down the output voltage on the CRO.
4. Plot the output waveforms on the graph.
5. Redesign the circuit to generate the sine wave of 1 KHz.
6. Plot the output waveform on the graph.
7. Compare the practical value of the frequency with the theoretical value.
Result:
Pre – Lab Test (20) Remarks &
Signature
With Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
LINEAR INTEGRATED CIRCUITS LAB
50
EXP.NO: 7 DATE: _ _ /_ _ / 2010
Astable and monostable multivibrators
Aim:
To design and test an astable and monostable multivibrators using ne555 timer.
Apparatus Required:
S.No Component Range Quantity
1. 555 TIMER 1
2. Resistors 3.3K, 6.8k 1
3. Capacitors 0.1 F 0.01 F 2
4. Diode In4001 1
5. CRO 1
6. Power
supply
15 V 1
7. Probe 2
8. Bread Board 1
Astable Multivibrators using 555
Fig shows the 555 timer connected as an Astable Multivibrators. Initially, when
the output is high. Capacitor C starts charging towards Vcc through RA and RB. As soon
as capacitor voltage equals 2/3 Vcc upper comparator (UC) triggers the flip flop and
the output switches low. Now capacitor C starts discharging through RB and transistor
Q1.
LINEAR INTEGRATED CIRCUITS LAB
51
Circuit Diagram
Model Graph
Vc
t(ms)
VUT
VUT
t high
tlow
t(ms)
VO
VOD
RA
6.8k
Vcc
+5 V
0.01µµµµF
0. 1µµµµF
RB
3.3k
7
2
6
1 5
8 4
3
5555
LINEAR INTEGRATED CIRCUITS LAB
52
Observation:
For output at pin no.3:Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For capacitor input: Peak to peak amplitude of the output = volts.
Charging time = sec
Discharging time = sec
Time period for 1 full cycle = sec
Frequency of the output = Hz
DESIGN:
Design an Astable Multivibrators for a frequency of ______KHz with a duty
cycle ratio of D = 50
fo = 1/T = 1.45 / (RA+2RB)C
Choosing C = 1 F; RA = 560
D = RB / RA +2RB= 0.5 [50%]
RB = ______
LINEAR INTEGRATED CIRCUITS LAB
53
When the voltage across C equals 1/3 Vcc lower comparator (LC), output
triggers the flip-flop and the output goes high. Then the cycle repeats.
The capacitor is periodically charged and discharged between 2/3 Vcc and 1/3
Vcc respectively. The time during which the capacitor charges form 1/3 Vcc to 2/3 Vcc is
equal to the time the output is high and is given by
T c = 0.69(RA+RB)C (1)
Where RA and RB are in Ohms and C is in farads.
Similarly the time during which the capacitor discharges from 2/3 Vcc to 1/3 Vcc is equal
to the time the output is low and is given by
T d = 0.69 RB C (2)
The total period of the output waveform is
T = T c + T d = 0.69 (RA + 2RB) C (3)
The frequency of oscillation
fo = 1 / T =1.45 / (RA+2RB)C (4)
Eqn (4) shows that fo is independent of supply voltage Vcc
The duty cycle is the ratio of the time td during which the output is low to the
total time period T. This definition is applicable to 555 Astable Multivibrators only;
conventionally the duty cycle ratio is defined as the ratio as the time during which the
output is high to the total time period.
Duty cycle = td× T × 100
RB + RA+ 2RB × 100
To obtain 50 % duty cycle a diode should be connected across RB and RA must
be a combination of a fixed resistor and a potentiometer. So that the potentiometer
can be adjusted for the exact square waves
LINEAR INTEGRATED CIRCUITS LAB
54
Circuit Diagram:
Model Diagram:
VO
RA
10k
Vcc
+5 V
0.01µµµµF
0. 1µµµµF
7
6
1 5
8 4
3
555
2Trigger i/p
0.01µµµµF
Vcc
0 V
(i) Trigger input
(ii) Output
(ii)Capacitor
Voltage
0 V
0 V
Vcc
LINEAR INTEGRATED CIRCUITS LAB
55
Observation
For trigger input:
Peak to peak amplitude of the input = volts.
Time period for 1 full cycle = sec
Frequency of the input = Hz
For output at pin no.3:
Peak to peak amplitude of the output = volts.
Time period for 1 full cycle = sec
Frequency of the output = Hz
For capacitor voltage:
Peak to peak amplitude of the output = volts.
Charging time = sec
Discharging time = sec
Monostable Multivibrator:
Design:
Given a pulse width of duration of 100 s
Let C = 0.01 mfd; F = _________KHz
Here, T= 1.1 RAC
So, RA =
LINEAR INTEGRATED CIRCUITS LAB
56
Monostable Multivibrators using 555
Monostable Multivibrators has one stable state and other is a quasi stable state.
The circuit is useful for generating single output pulse at adjustable time duration in
response to a triggering signal. The width of the output pulse depends only on
external components, resistor and a capacitor.
The stable state is the output low and quasi stable state is the output high. In the
stable state transistor Q1 is ‘on’ and capacitor C is shorted out to ground. However
upon application of a negative trigger pulse to pin2, Q1 is turned ‘off’ which releases
the short circuit across the external capacitor C and drives the output high. The
capacitor C now starts charging up towards Vcc through RA. However when the
voltage across C equal 2/3 Vcc the upper comparator output switches form low to high
which in turn drives the output to its low state via the output of the flip flop. At the
same time the output of the flip flop turns Q1 ‘on’ and hence C rapidly discharges
through the transistor. The output remains low until a trigger is again applied. Then
the cycle repeats.
The pulse width of the trigger input must be smaller than the expected pulse
width of the output. The trigger pulse must be of negative going signal with amplitude
larger than 1/3 Vcc. The width of the output pulse is given by,
T = 1.1 RAC
LINEAR INTEGRATED CIRCUITS LAB
57
Procedure:
1. Rig-up the circuit of 555 Astable Multivibrators as shown in fig with the
designed value of components.
2. Connect the CRO probes to pin 3 and 2 to display the output signal and the
voltage across the timing capacitor. Set suitable voltage sensitively and time-
base on the CRO.
3. Switch on the power supply to CRO and the circuit.
4. Observe the waveforms on the CRO and draw to scale on a graph sheet.
Measure the voltage levels at which the capacitor starts charging and
discharging, output high and low timings and frequency.
5. Switch off the power supply. Connect a diode across RB as shown in dashed
lines in fig to make the Astable with 50 duty cycle ratio. Switch on the power
supply. Observe the output waveform. Draw to scale on a graph sheet.
Procedure:
Monostable Multivibrator:
1. Rig-up the circuit of 555 monostable Multivibrators as shown in fig with the
designed value of components.
2. Connect the trigger input to pin 2 of 555 timer form the function generator.
3. Connect the CRO probes to pin 3 and 2 to display the output signal and the
voltage across the timing capacitor. Set suitable voltage sensitively and time-
base on the CRO.
4. Switch on the power supply to CRO and the circuit.
5. Observe the waveforms on the CRO and draw to scale on a graph sheet.
Measure the voltage levels at which the capacitor starts charging and
discharging, output high and low timings along with trigger pulse.
LINEAR INTEGRATED CIRCUITS LAB
58
Result:
Pre – Lab Test (20) Remarks &
Signature
With Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
LINEAR INTEGRATED CIRCUITS LAB
60
EXP.NO: 8 DATE: _ _ /_ _ / 2010
PLL characteristics and its use as Frequency Multiplier.
Aim:
To design a PLL characteristics and its use as Frequency Multiplier.
Apparatus Required:
S.No Component Range Quantity
1. IC NE565,74c90 1
2. Resistors
3. Capacitors
5. CRO 1
6. Power
supply
15 V 1
7. Probe 2
8. Bread Board 1
Theory
Phase locked loops are used for frequency control. They can be configured as
frequency multipliers, demodulators, tracking generators or clock recovery circuits.
Each of these applications demands different characteristics but they all use the same
basic circuit concepts. The block diagram consist of a feedback control system that
controls the phase of a voltage controlled oscillator(VCO). The input signal is applied
to one input of phase detector. The other input is connected to the output of a divide
by N counter. Normally the frequencies of both signals will be nearly the same. The
output of the phase detector is a voltage, proportional to the phase difference
LINEAR INTEGRATED CIRCUITS LAB
61
between the two inputs. This signal is applied to the phase difference between the
two inputs, this signal is applied to the loop filter. The loop filter determines the
dynamic characteristics of the PLL. The filtered signal controls the VCO. Note that the
output of the VCO is at a frequency that is N times the input supplied to the frequency
reference input. This output signal is sent back to the phase detector via a divided by N
counter. Normally the loop filter is designed to match the characteristics required by
the application of the PLL. If the PLL is to acquire and track a signal bandwidth of the
loop filter will be greater than if it expects a fixed input frequency. The frequency
range which the PLL will accept and lock on is called the capture range. Once the PLL
is locked and tracking a signal the range of frequencies that the PLL will follow is
called track range. Generally the tracking range is larger than the capture range. The
loop filter also determines how fast the signal frequency can change and still maintain
lock. This is the maximum slewing rate. The narrower the filters bandwidth the
smaller the achievable capture range.
LINEAR INTEGRATED CIRCUITS LAB
63
PLL characteristics:
Free running Mode
Peak to peak amplitude of free running =
Frequency of free running =
Time =
Locked mode
Peak to peak amplitude of locked mode =
Frequency of locked mode =
Time =
Output
Peak to peak amplitude of output =
Frequency of output =
Time =
Frequency Multiplier
Input:
Peak to peak amplitude of input =
Frequency =
Time period =
Output:
Peak to peak amplitude of output =
Frequency =
Time period =
LINEAR INTEGRATED CIRCUITS LAB
64
Result:
Pre – Lab Test (20) Remarks &
Signature
With Date
Simulation (20)
Circuit Connection (30)
Result (10)
Post – Lab Test (20)
Total (100)
LINEAR INTEGRATED CIRCUITS LAB
65
CIRCUIT DIAGRAM:
Low Voltage Regulator
430
1k
0.52N3055Unregulated
DC Power
Supply 12 11
6
5
R1
R2
V+ VcVo
CL
CS
INV
COMPV-
NI
Vref
0.1
UF
TIP122
100pF
Rsc
10
2
3
4
137
Load
A
+ -
V
+
-
DESIGN:
Output voltage → VO
Reference voltage→ Vref
Rprotect → Minimum Resistance to protect the output from short circuit.
Low Voltage Regulator:
Given: Vo=5V, Vref = 7.15 V To calculate R1, R2, R3 and Rsc.
Vo = Vref ( R2 / ( R1 + R2 ) )
5 / 7.15 = ( R2 / ( R1 + R2 ) )
(R1 + R2) 0.699= R2
0.699R1 = 0.301 R2, R1 = 0.4306 R2
Select R2 = 1 KΩΩΩΩ
R1 = 1 KΩ * 0.4306 = 430Ω
R1 = 430ΩΩΩΩ R3 = R1 * R2 / (R1 + R2), R3 = 430.6 *1000 / (430.6+1000)
R3 = 300ΩΩΩΩ
Rsc = Vsense / Ilimit = 0.5 /1A = 0.5Ω , Rsc = 0.5ΩΩΩΩ
LM723
LINEAR INTEGRATED CIRCUITS LAB
66
EXP.NO.9: DATE: _ _ /_ _ / 2010
DC power supply
AIM:
To design a DC power supply using LM317 and LM723
COMPONENTS REQUIRED:
S.NO COMPONENTS SPECIFICATION QUANTITY
1. Transistors TIP122,2N3055 1 each
2. Integrated Circuit LM723 1
3. Digital Ammeter ( 0 – 10 ) A 1
4. Digital Voltmeter ( 0 – 20 ) V 1
5. Variable Power Supply ( 0 – 30 ) V-2A 1
6.
Resistors 300Ω,430Ω,1KΩ,678KΩ,678Ω
1Ω
1 each
2
7. Capacitors 0.1µF,100pF 1 each
9. Rheostat ( 0 – 350 ) Ω 1
THEORY
GENERAL PURPOSE REGULATOR 723
723 IC is a general purpose regulator, which can be adjusted over a wide range
of both positive and negative regulated voltage. Though the IC is a low current device,
current can be boosted to provide 5 amps or more.
LINEAR INTEGRATED CIRCUITS LAB
67
CIRCUIT DIAGRAM:
High Voltage Regulator:
High Voltage Regulator:
Given : Vo=12V, Vref = 7.15 V
To calculate R1, R2, R3 and Rsc.
Vo = Vref ( 1 + (R1 / R2) )
12 / 7.15 = 1+ (R1 / R2)
(12 / 7.15) - 1 = (R1 / R2)
(R1 / R2) = 0.678
Select R2 = 1 KΩΩΩΩ
R1 = 1 KΩ * 0.678 = 678Ω
R1= 678ΩΩΩΩ
Rsc = Vsense / Ilimit = 0.5 /1A = 0.5Ω
Rsc = 0.5ΩΩΩΩ
LINEAR INTEGRATED CIRCUITS LAB
68
It has short circuit protection and no short circuit current limits. It can operate with an
input voltage from 9.5V to 40V and provide output voltage from 2V to 37V.
723 IC has two sections. One section provides a fixed voltage of 7V at the terminal Vref. Other section consists of an error amplifier and two transistors. These two sections are not internally connected.
LOW VOLTAGE REGULATOR
Vref point is connected through a resistance to the non-inverting terminal and
the output if feedback to the inverting terminal of the error amplifier. If the output
voltage becomes low, the voltage at the inverting terminal of error amplifier also goes
down. This makes the output of the error amplifier becomes more positive, thereby
driving transistor more into conduction. This reduces voltage across the transistor and
drives more current into the load causing voltage across load to increase.
HIGH VOLTAGE REGULATOR
If it is desired to produce regulated output voltage greater than 7V, a small
change should be made in the circuit for low voltage regulator. The non-inverting
terminal is connected directly to Vref. So the voltage at the non-inverting terminal is
Vref. The error amplifier operates as a non-inverting amplifier.
PROCEDURE:
LOW VOLTAGE REGULATOR:
Line Regulation:
1. Give the circuit connection as per the circuit diagram.
2. Set the load Resistance to give load current of 0.25A.
3. Vary the input voltage from 7V to 18V and note down the corresponding output
voltages.
LINEAR INTEGRATED CIRCUITS LAB
69
4. Similarly set the load current (IL) to 0.5A & 0.9A and make two more sets of
measurements.
Tabulation of the Measurements:
LOW VOLTAGE REGULATOR:
Line Regulation:
S.No. Load Resistance RL1 = Load Resistance RL2 = Load Resistance RL3 =
Input
Voltage
Vin(Volts)
Output
Voltage
VL(Volts)
Input
Voltage
Vin(Volts)
Output
Voltage
VL
(Volts)
Input
Voltage
Vin(Volts)
Output
Voltage
VL (Volts)
LINEAR INTEGRATED CIRCUITS LAB
70
Load Regulation:
S.No. Input Voltage Vin1 = Input Voltage Vin2 = Input Voltage Vin3 =
Output
Current
IL ( A )
Output
Voltage
VL (Volts)
Output
Current
IL ( A )
Output
Voltage
VL (Volts)
Output
Current
IL ( A )
Output
Voltage
VL (Volts)
Load Regulation:
1. Set the input voltage to 10V.
2. Vary the load resistance in equal steps from 350Ω to 5Ω and note down the
corresponding output voltage and load current.
3. Similarly set the input voltage (Vin) to 14V & 18V and make two more sets of
measurements.
Lab Report:
1. Plot the line regulation by taking Input Voltage (Vin) along X-axis and Output
Voltage (VL) along Y-axis for various load currents.
2. Plot the load regulation by taking load current (IL) along X-axis and Output
Voltage (VL) along Y-axis for various input voltages.
3. Calculate its % Voltage Regulation using the formula.
LINEAR INTEGRATED CIRCUITS LAB
71
HIGH VOLTAGE REGULATOR:
Line Regulation:
1. Give the circuit connection as per the circuit diagram.
2. Set the load Resistance to give load current IL of 0.25A.
3. Vary the input voltage from 7V to 18V and note down the corresponding output
voltages.
4. Similarly set the load current (IL) to 0.5A & 0.9A and make two more sets of
measurements.
Load Regulation:
1. Set the input voltage to 10V.
2. Vary the load resistance in equal steps from 350Ω to 15Ω and note down the
corresponding output voltage and load current.
3. Similarly set the input voltage (Vin) to 14V & 18V and make two more sets of
measurements.
LINEAR INTEGRATED CIRCUITS LAB
72
HIGH VOLTAGE REGULATOR:
Line Regulation:
S.No. Load Resistance RL1 = Load Resistance RL2 = Load Resistance RL3 =
Input
Voltage
Vin(Volts)
Output
Voltage
VL(Volts)
Input
Voltage
Vin(Volts)
Output
Voltage
VL
(Volts)
Input
Voltage
Vin(Volts)
Output
Voltage
VL(Volts)
LINEAR INTEGRATED CIRCUITS LAB
73
Load Regulation:
S.No. Input Voltage Vin1 = Input Voltage Vin2 = Input Voltage Vin3 =
Output
Current
IL ( A )
Output
Voltage
VL(Volts)
Output
Current
IL ( A )
Output
Voltage
VL(Volts)
Output
Current
IL ( A )
Output
Voltage
VL(Volts)
Lab Report:
1. Plot the line regulation by taking Input Voltage (Vin) along X-axis and Output
Voltage (VL) along Y-axis for various load currents.
2. Plot the load regulation by taking load current (IL) along X-axis and Output
Voltage (VL) along Y-axis for various input voltages.
3. Calculate its % Voltage Regulation using the formula.
Calculation of % Voltage Regulation:
% Voltage Regulation = ( Vdc ( NL ) - Vdc ( FL ) ) / Vdc ( FL )
Vdc (NL) = D.C. output voltage on no load
Vdc (FL) = D.C. output voltage on full load
LINEAR INTEGRATED CIRCUITS LAB
74
Model Graph:
Line Regulation: Load Regulation:
Input Voltage Vs Output Voltage: Output Current Vs Output Voltage:
I L
V 0 V 0
V in
Load regulation Line regulation