The document discusses integrated circuits and operational amplifiers. It begins by defining an integrated circuit and listing its advantages. It then describes the two main types of integrated circuits - linear and digital ICs. The document goes on to explain operational amplifiers in detail, including their ideal characteristics, block diagram, equivalent circuit model, open-loop configurations, and applications. It also provides information about specific op-amps like the 741 and TL082, discussing their features, input and bias currents, and common mode rejection ratio.

1. INTEGRATED CIRCUITS
AND APPLICATIONS
UNIT-I
OPERATIONALAMPLIFIER

2. Integrated Circuits
It is a miniature, low cost electronic circuit consisting of both
active and passive components that are irreparably joined
together on a single crystal of silicon.
ADVANTAGES OF INTEGRATED CIRCUITS
Compact size
 Lesser weight
 Low power consumption
 Reduced cost
 Increased reliability
 Improved operating speeds

3. TYPES OF INTEGRATED CIRCUITS
Linear IC: It can take on a continuous range of values and outputs
are generally proportional to the inputs.
Digital IC: It has circuits whose inputs and outputs are limited to
only two possible levels LOW or HIGH.
DIFFERENCE BETWEEN LINEAR IC & DIGITAL IC
ANALOG IC DIGITAL IC
It has analog inputs and analog outputs It has digital inputs and digital outputs
Also called as Linear IC Also called as Non-Linear IC
Used in aircraft, space, vehicles, radars,
oscilloscopes, etc
Used in microprocessors, PCs, calculators,
digital watches, etc
Contains less no. of transistors Contains more no. of transistors
Ex.: 741, TL082, 555, 565.. Ex.: 74x00, 74x02,74x151…

4. • Digital IC’s are used to form circuits such as Gates,
Counters, Multiplexers, De multiplexers ,shift registers
and others..,
• Linear IC’s are used to form circuits such as amplifiers,
filters, frequency multipliers and modulators that often
require additional components for satisfactory operation.
Also referred as analog circuits.
• OP-Amps are again classified as
• General purpose: used for variety of applications such as
Integrator , Differentiator, summing amplifier etc.., Ex:
741 IC
• Special purpose: used for the specific applications they
are designed.Ex:LM380 can be used only for audio
applications

5. • Integrated circuits may be classified as either Monolithic
or Hybrid.
• Most linear IC’s are produced by the monolithic process
in that all transistors and passive elements are fabricated
on a single piece of semiconductor material usually
silicon.
• In Hybrid IC’s passive components and the
interconnections between them are formed on an
insulating substrate. Active components as well as
Monolithic IC’s are then connected to form a complete
circuit.

6. IC MANUFACTURING COMPANIES
COMPANY SERIES
Fair child μA, μAF
Motorola MC, MFC
Burrbrown BB
Signetics N/S, NE/SE
Texas Instruments SN
National Semiconductor LH, LM, LF
RCA CA, CD

7. • IC’s are classified according to number of
components as

8. Introduction
• An operational Amplifier(Op-Amp) is a direct-coupled
high gain amplifier usually followed by a level translator
and an output stage.
• The Op-Amp is a versatile device that can be used to
amplify DC as well as AC input signals and was originally
designed for performing mathematical operations such as
addition, subtraction, multiplication and integration.
• With the addition of suitable external feedback
components, the modern day op-amp can be used for a
variety of applications such as AC & DC signal
amplification , active filters, oscillators, comparators,
regulators etc..,

9. DIFFERENTIAL AMPLIFIER
The Differential Amplifier is
the basic building block of
operational amplifiers.
The differential amplifier, as
its name implies, amplifies
the difference between two
input signals Vin1 and Vin2.
The differential amplifier is
also referred to as a
Difference Amplifier.

10. DIFFERENTIAL AMPLIFIER CONFIGURATIONS
 The configurations listed are defined by the number of input signals used and
the way an output voltage is measured.
 If we use two input signals, the configuration is said to be Dual Input;
otherwise, it is a Single Input configuration.
 On the other hand, if the output voltage is measured between two collectors,
it is referred to as a Balanced Output.
 However, if the output is measured at one of the collectors with respect to
ground, the configuration is called as an Unbalanced Output.
1. Dual- Input, Balanced Output Differential Amplifier
2. Dual-Input, Unbalanced Output Differential Amplifier
3. Single-Input, Balanced Output Differential Amplifier
4. Single-Input, Unbalanced Output Differential Amplifier

11. BLOCK DIAGRAM OF OP-AMP
Fig : Block diagram of a typical Op-amp
Input Stage
 The input stage is the Dual-Input, Balanced-Output differential amplifier. This
stage generally provides most of the voltage gain of the amplifier and also
establishes the input resistance of Op-amp.

12. Intermediate Stage
 The intermediate stage is Dual-Input, Unbalanced (Single-Ended) Output.
Because direct coupling is used, the DC voltage at the output of the intermediate
stage is well above ground potential.
Level Shifting Stage
 The level translator (Shifting) circuit is used after the intermediate stage to shift
the DC level at the output of the intermediate stage downward to zero volts with
respect to ground.
Output Stage
 The final stage is usually a push pull complementary amplifier output stage; it
increases the output voltage swing and raises the current supplying capability of
the Op-amp. A well designed output stage also provides low output resistance.

13. CURRENT MIRROR (or) CONSTANT CURRENT
SOURCE
A constant current source makes use of
fact that for a transistor in the active
mode of operation, the collector
current is relatively independent of
collector voltage.
 Since both transistors are matched
their collector currents and base
currents are equal,
i.e. IC1 = IC2 and IB1 = IB2
 Since ‘β’ is very large value,
IREF = IC2 and

14. LEVEL TRANSLATOR
In the cascade arrangement because of direct coupling no
coupling capacitors are used. Therefore, the DC voltage at the
output terminals tends to rise above the ground.
If several amplifiers are cascaded, the effect is cumulative. This
affects the output voltage swing and causes amplitude
distortion.
This is not desirable; therefore the DC level is brought down to
ground level (i.e., Zero) by means of a level translator.
Basically the level translator is an emitter follower(Common
Collector Amplifier). A simple level translator is shown in
figure.

15. CIRCUIT SYMBOL OF AN OPEARTIONALAMPLIFIER
 The circuit symbol of an Op-Amp is a triangular as shown in figure.
 It has two input terminals and one output terminal.
 The +VCC and –VEE power supply terminals are connected to two DC Voltage
sources.

16. • *Estimate ICQ, VCEQ, re, voltage gain, input and output resistances
for a dual-input, balanced-output differential amplifier with circuit
parameters RC = 2.2 kΩ, RE = 4.7 kΩ, Rin1 = Rin2 = 50 Ω,
VCC = +10 V, ‫׀‬-VEE‫׀‬ = 10 V, 𝛽𝐷𝐶 = 𝛽𝐴𝐶 = 100 and 𝑉𝐵𝐸 = 0.71V.
• Solution: ICQ=IE =[(VEE-VBE)/(2RE+Rin/β)]
– ICQ=IE =[10-0.71]/[2*4700+(50/100)] = 0.988mA
• VCEQ = VCE = VCC + VBE - ICQ RC
• VCEQ = VCE =10 + 0.71- 0.988*10-3 = 8.53V
• The ac emitter resistance re=VT/IE=25mV/IE =25mV/0.988mA =
25.3 Ω
• Voltage Gain Ad=Vo/Vid=RC/re =2200/25.3 = 86.96
• Input Resistance Ri=2βac re =2*100*25.3 = 5.06KΩ
• Output Resistance Ro =RC = 2.2KΩ

17. • *A dual input, unbalanced-output differential amplifier has
the following specification: |Vcc| = 10 V,|-VEE| = 10 V, Rc1 =
Rc2 = 2.7 kΩ, Rin = 50 Ω and RE = 3.9 kΩ and the transistor
is CA3086 with βac = βdc = 100 and VBE = 0.715 V.
Calculate: (i) ICQ and VCEQ values. (ii) Voltage gain. (iii)
Input and output resistances.
• Solution: ICQ=IE =[(VEE-VBE)/(2RE+Rin/β)]
– ICQ=IE =[10-0.71]/[2*3900+(50/100)] = 1.19mA
• VCEQ = VCE = VCC + VBE - ICQ RC
• VCEQ = VCE =10 + 0.71 - 1.19*10-3 = 7.502V
• The ac emitter resistance re=VT/IE=25mV/IE
=25mV/1.19mA = 21 Ω
• Voltage Gain Ad=Vo/Vid=RC/2re =2700/(2*21) = 64.28
• Input Resistance Ri=2βac re =2*100*21 = 4.2KΩ
• Output Resistance Ro =RC = 2.7KΩ

18. THE IDEAL OP-AMP
 An Ideal Op-amp would exhibit the following electrical characteristics:
1. Infinite open loop voltage gain (AOL = ∞).
2. Infinite input resistance (Ri) so that almost any signal source can drive it
and there is no loading of the preceding stage (Ri = ∞).
3. Zero output resistance (RO) so that output can drive an infinite number of
other devices (RO = 0).
4. Zero output voltage when input voltage is zero.(Zero offset i.e. VO = 0
when V1 = V2 =0).
5. Infinite bandwidth so that any frequency signal from 0 to ∞ Hz can be
amplified without attenuation (BW = ∞).
6. Infinite Common-mode rejection ratio so that the output common-mode
noise voltage is zero (CMMR= ∞).
7. Infinite slew rate so that output voltage changes occur simultaneously with
input voltage changes (SR= ∞).

19. EQUIVALENT CIRCUIT OF AN OP-AMP

20. EQUIVALENT CIRCUIT OF AN OP-AMP (CONT…)
 The equivalent circuit is useful in analyzing the basic operating principles of
Op-amps and in observing the effects of feedback arrangements.
• Output voltage, VO = A Vid
VO = A (V1- V2) ---------①
Where A=Large Signal Voltage Gain
Vid=Difference input voltage
V1=Voltage at the Non-Inverting terminal wrt to Ground.
V2=Voltage at the Inverting terminal wrt to Ground.
 Equation ① indicates that the output voltage VO is directly proportional to
the algebraic difference between the two input voltages.
 In other words, the Op-amp amplifies the difference between the two input
voltages; it does not amplify the input voltages themselves. For this reason
the polarity of the output voltage depends on the polarity of the difference
voltage.

21. OPEN-LOOP OP-AMP CONFIGURATIONS
 In the case of amplifiers the term open loop indicates that, the output
signal is not feedback in any form as part of the input signal and the
loop that would have been formed with feedback is open.
 When connected in open-loop connection, the Op-amp simply
functions as a high-gain amplifier.
 There are three open-loop Op-amp configurations:
1. Differential Amplifier
2. Inverting Amplifier
3. Non Inverting Amplifier
 These configurations are classified according to the number of inputs
used and the terminal to which the input is applied when single input
is used.

22. 1. THE DIFFERENTIALAMPLIFIER

23. THE DIFFERENTIAL AMPLIFIER (CONT…)
Figure shows the open-loop differential amplifier in which input
signals Vin1 and Vin2 are applied to the positive and negative
input terminals.
Since the Op-amp amplifies the difference between the two
input signals, this configuration is called the differential
amplifier.
The source resistances Rin1 and Rin2 are normally negligible
compared to the input resistance Ri.
Therefore, the voltage drops across these resistors can be
assumed to be zero, which implies that V1 = Vin1 and Vin2.
VO = A (Vin1 - Vin2)

24. 2. INVERTING AMPLIFIER

25. 2. INVERTING AMPLIFIER(Contd..,)
In the Inverting Amplifier only one input is applied and that is
to the inverting input terminal. The Non Inverting input terminal
is grounded.
– Here, V1 = 0 and V2 = Vin
– The basic Op-amp equation,
– VO = AVid
– VO = A (V1 - V2) = A (0 - Vin)
– VO = - A Vin
The negative sign indicates the output voltage is out of phase
with respect to input.

26. 3. NON INVERTING AMPLIFIER

27. 3. NON INVERTING AMPLIFIER(Contd..,)
In this configuration the input is applied to the non
inverting input terminal, and the inverting terminal is
connected to ground.
In this circuit, V1 = Vin and V2 = 0V.
The basic Op-amp equation,
– VO = A Vid
– VO = A (V1 - V2) = A(Vin - 0)
– VO = A Vin
In this configuration, the output voltage is in phase with
the input voltage.

28. OP-AMP APPLICATIONS
• Adder
• Integrator and Differentiator
• Instrumentation Amplifier
• Active Filters
• Precision Rectifiers
• Comparator
• Schmitt Trigger
• Oscillator
• Sample and Hold Circuit
• Multivibrator
• Regulators etc..,

29. Power Supply Configurations of OP-Amp
• Most linear ICs use one or more differential amplifier stages, and
differential amplifiers require both a positive and negative power supplies
for proper operation of the circuit.
• This means that most linear ICs need both a positive and a negative power
supplies.
• Some linear ICs need both a positive and a negative power supply. A few
linear ICs use unequal power supplies.
• Ex:702 op-amp IC requires unequal power supplies
324 op-amp IC requires only a positive power supply .
• 741 op-amp IC requires two power supplies with equal in magnitude.
• Thus, for 741 op-amp pin7 is a positive supply pin and pin4 is a negative
supply pin.

30. 741 OP-AMP

31. TL082 OP-AMP

32. Features of 741 OP-Amp
• No External frequency compensation required.
• Short Circuit Protection
• Offset null Capability
• Large common mode differential voltage ranges
• Low Power Consumption
• No Latch-up Problem

33. Input Offset Voltage
• It is the voltage that must be applied between the two
input terminals of an op-amp to null the output.
• Here V1 and V2 are dc voltages and Ra represents the
source resistance.
• We denote the input Offset voltage by Vio. This
voltage vio could be positive or negative.
• Therefore its absolute value is listed on the data sheet
For a 741C the maximum value of Vio is 6mv DC.
• The smaller the value of Vio, the better the input
terminals are matched.
• For instance, the 741C precision op-amp has
Vio=150μv.

35. Input Offset Current
• The algebraic difference between the currents in to the inverting
and non inverting terminals is referred to as input offset current Iio.
Iio=|IB1-IB2|
• Where IB1 is the current in to the Non Inverting Input.
IB2 is the current in to the Inverting Input.
• The Input Offset Current for the 741C is 200nA maximum.
• As the matching between the two input terminals is improved,
the difference between the IB1 and IB2 becomes smaller.
• For instance, the precision op-amp 741C has a maximum value
of Iio equal to 6nA.

36. Input Bias Current
• It is defined as the average of the two input bias currents
that flow in to the inverting and non-inverting input
terminals of the op-amp.
• Actually the input bias currents IB1 and IB2 are the base
bias currents of the two transistors in the input differential
amplifier stage of the op-amp.
• IB=500nA maximum at supply voltages for = ±15v dc for
the 741C op-amp,

37. Common Mode Rejection Ratio(CMRR)
• When the same input voltage is applied to both input terminals of
an op-amp, then the op-amp is said to be operating in common
mode configuration. A common mode voltage vcm can be ac or dc.
• Thus the common mode voltage gain Acm is much smaller than
1.Ideally it is zero.
• Generally it can be defined as the ratio of the differential gain AD
to the common mode gain Acm, that is
Generally, the CMRR is very large and is therefore usually specified
in decibles (dB).

38. Calculate the CMRR for the circuit below

39. Slew Rate
• It is defined as the maximum rate of change of output voltage with
respect to time , usually specified in V/µs.
• For example , a 1V/ µs slew rate means that the output raises or
falls no faster than 1 V every microsecond.
• We would like an infinite slew rate so that the op-amps output
voltage would change simultaneously with the input.
• The practical op-amps are available with slew rates from 0.1 V/µs
to above 1000 V/µs.

40. Slew Rate

41. Thermal Voltage Drift
• The average rate of change of input offset voltage per unit change
in temperature is called thermal voltage drift . It is expressed in
µv/ºC.
=15 µv/ºC maximum

42. Input Bias Current Drift
• It is defined as the average rate of change of
input bias current per unit change in
temperature. It is measured in pA/ºC.
=200 pA/ºC maximum

43. Causes of Slew Rate
• Slew rate is caused by current limiting and the saturation of internal
stages of an op-amp when a high frequency, large amplitude signal
is applied.
• We know that the capacitor requires a finite amount of time to
charge and discharge. Thus the internal capacitors prevent the
output voltage from responding immediately to a fast changing
input.
Thus slew rate limiting is caused by the capacitor charging rate , in
which the voltage across the capacitor is the output voltage.

44. Effect of Slew Rate
• The slew rate has important effects on both open loop and closed
loop op-amp circuits.

46. Compute slew rate of Closed loop Circuit with a gain of 50 at
about 20 KHz ?
Ans:Vp=3.98V,Vin=159 mv

47. Supply Voltage Rejection Ratio
• The lower the value of SVRR ,the better the op-amp
performance , Infact ideally the value of SVRR should be zero.

48. Gain Bandwidth Product

50. Frequency Response
• The manner in which the gain of the op-amp responds
to different frequencies is called the frequency
response.
• Thus variation in operating frequency will cause
variation in gain magnitude and its phase angle.
• Remember that to accommodate large frequency
ranges the frequency the assigned to logarithmic
scale, just as the gain magnitude is assigned a linear
scale and is expressed in decibels to accommodate
very high gain on the order of 105 or higher.

51. Compensating Networks
• Generally for an amplifier ,as the operating frequency increases, two
effects become more evident.
• (a).The gain of the amplifier decreases.
• (b).The phase shift between the input and output signals increases.
• Above two effects are due to the internally integrated capacitors as
well as stray capacitances.
• These capacitances are due to the physical characteristics of
semiconductor devices(BJTs & FETs) and internal construction of
op-amp.
• The rate of change of gain as well as the phase shift of an op-amp
can be changed by using resistors and capacitors.
• The circuit formed by such components and used for modifying the
rate of change of gain and phase shift is called compensating Circuit.

52. • Thus the main purpose of compensating network is to modify the
performance of an op-amp over the desired frequency range by
controlling its gain and phase shift.
• There are two types of op-amps:
• (a)Internally Compensated (b) Externally Compensated
• In the Internally compensated op-amps ,the compensating circuit is
designed in the circuit to control the gain and phase shift of an op-
amp.
• Examples: Later generation’s of amp such as 741and 351.
• In Externally compensated op-amps, the compensating components
such as resistors and capacitors are added at designated terminals
for proper operation.
• Examples : First generation op-amps such as 709 requires external
compensating network.
Compensating Networks (contd..,)

53. Frequency Response of Internally
compensated op-amp 741

54. Frequency Response of Non-
compensated op-amp µA 709

55. Transient Response
• The transient response is that portion of the
complete response before the output attains some
fixed value i.e.., steady state value.
• The transient response is time variant. The rise
time and over shoot are characteristics of transient
response.
• The transient response of any practically useful
network to given input is composed of Transient
and steady state response.

56. Transient Response