operational amplifier (op-amp) · “operational” was used as a descriptor early-on because this...

Operational Amplifier (Op-Amp)

Microelectronic Circuits - Fifth Edition © Sedra/Smith®

Prodi S1-SK

2017

Operational Amplifiers

One might ask, why are operational amplifiers

included in Basic Electric Circuits?

The operational amplifier has become so cheap in

price (often less than $1.00 per unit) and it can be

used in so many applications, we present an

introductory study early-on in electric circuits.

What is an operational amplifier? This particular

form of amplifier had the name “Operational”

attached to it many years ago.

As early as 1952, Philbrick Operational Amplifiers

(marketed by George A. Philbrick) were constructed

with vacuum tubes and were used in analog

computers.* Even as late as 1965, vacuum tube

operational amplifiers were still in use and cost in the

range of $75.

* Some reports say that Loebe Julie actually developed the operational amplifier circuitry.

Operational Amplifiers

The Philbrick Operational Amplifier

From “Operational Amplifier”, by Tony van Roon: http://www.uoguelph.ca/~antoon/gadgets/741/741.html

Operational Amplifiers

“Operational” was used as a descriptor

early-on because this form of amplifier can perform

operations of

• adding signals

• subtracting signals

• integrating signals, dttx )(

The applications of operational amplifiers ( shortened

to op amp ) have grown beyond those listed above.

Operational Amplifiers

At this level of study we will be concerned with how

to use the op amp as a device.

The internal configuration (design) is beyond basic

circuit theory and will be studied in later electronic

courses. The complexity is illustrated in the following

circuit.

Operational Amplifiers

The op amp is built using VLSI techniques. The circuit

diagram of an LM 741 from National Semiconductor is

shown below. V+

V-

Vo

Vin(-)

Vin(+)

Taken from National Semiconductor

data sheet as shown on the web.

Operational Amplifiers

Fortunately, we do not have to sweat a circuit with 22

transistors and twelve resistors in order to use the op amp

The circuit in the previous slide is usually encapsulated into

a dual in-line pack (DIP). For a single LM741, the pin

connections for the chip are shown below.

Taken from National Semiconductor

data sheet as shown on the web.

Operational Amplifiers

inverting input

noninverting input

output

V-

V+

The basic op amp with supply voltage included is shown

in the diagram below.

Operational Amplifiers

In most cases only the two inputs and the output are

shown for the op amp. However, one should keep in

mind that supply voltage is required, and a ground.

The basic op am without a ground is shown below.

Operational Amplifiers

Inverting input

Non-inverting input

Output

A model of the op amp, with respect to the symbol, is

shown below.

V1

V2

_

+

Vd Ri

Ro

AVd

Vo

Operational Amplifiers

The previous model is usually shown as follows:

Ri

Ri

AVd

_

+

Vd

V1

V2

Vo

+

_

Operational Amplifiers

Application: As an application of the previous model,

consider the following configuration. Find Vo as a

function of Vin and the resistors R1 and R2.

+

_

R2

R1

+

_

+

_

VinVo

Operational Amplifiers

In terms of the circuit model we have the following total

op amp schematic for voltage gain configuration :

Ri

Ri

AVi

_

+

ViVin Vo

+

_

+

_

R1

R2

ab

Operational Amplifiers

Ri

Ri

AVi

_

+

ViVin Vo

+

_

+

_

R1

R2

ab

Given circuit values :

R1 = 10 k R2 = 40 k

A = 100,000 Ri = 1 M

Ro = 50

Operational Amplifiers

We can write the following equations for nodes a and b.

(Eq 8.1)

(Eq 8.2)

ioin

o

oiiiin

AVk

)VV(V

k

VV

meg

V

k

)VV(

4050

40110

Operational Amplifiers

Equation 8.1 simplifies to:

inio VVV 10012625

Equation 8.2 simplifies to:

010410005.4 95 io VxVx

Operational Amplifiers

(Eq 8.3)

(Eq 8.4)

From Equations 8.3 and 8.4 we find;

ino VV 99.3

This is an expected answer.

Fortunately, we are not required to do elaborate circuit

analysis, as above, to find the relationship between the

output and input of an op amp. Simplifying the analysis

is our next consideration.

Operational Amplifiers

(Eq 8.5)

For most all operational amplifiers, Ri is 1 meg or

larger and Ro is around 50 or less. The open-loop gain,

A, is greater than 100,000.

Based on those values, the following assumptions are

made for the ideal op amp:

i

o

RohmsinputInfinite

RohmsoutputZero

AgainloopopenInfinite

;.3

0;.2

;.1

Ideal Op-Amp

_

+ ++

+

+

_

__ _

Vi

V1

V2 = V1

Vo

i1

i2

= 0

= 0

(a) i1 = i2 = 0, due to infinite input resistance.

(b) Vi is negligibly small, so V1 = V2.

Ideal Op-Amp

Find Vo in terms of Vin for the following configuration if

R1 = 1 k and R2 = 4 k.

+

_

R2

R1

+

_

+

_

VinVo

Ideal Op-Amp

+

_

R2

R1

+

_

+

_

VinVo

a

Vi

Writing a nodal equation at (a) gives;

21

)(

R

VV

R

VV oiiin

Ideal Op-Amp

(Eq 8.6)

21

)(

R

VV

R

VV oiiin

With Vi = 0 we have;

With R2 = 4 k and R1 = 1 k, we have

ino VV 4 Earlier

we got ino VV 99.3

inVR

RV

1

20

(Eq 8.7)

Ideal Op-Amp

When Vi = 0 in Eq 8.7 and we apply the Laplace Transform;

1

20

R

R

)s(V

)s(V

in

In fact, we can replace R2 with Zfb(s) and R1 with Z1(s) and

we have the important expression;

)s(Z

)s(Z

)s(V

)s(V

in

fb

in

0

Ideal Op-Amp

(Eq 8.8)

(Eq 8.9)

Example 8.1: Inverting Amplifier.

Consider the op amp configuration below. Determine

VO and Vin relation if assume Vin = 5 V

+

+

+

_

__

3 V

Vin

6 k

1 k

V0

a

+

+

+

_

__

3 V

Vin

6 k

1 k

V0

a

At node “a” we can write:

k

V

k

)V( in

6

3

1

3 0

From which Vin = 5 V, then V0 = -51 V

Example 8.1 continued

(Eq 8.10)

Example 8.2: Summing Amplifier. Given the following

Rfb

R1

R2

V2

V1V0

a

Equation at node “a” is:

fbR

V

R

V

R

V 0

2

2

1

1 (Eq 8.11)

Example 8.2 continued

Equation 8.11 can be expressed as;

2

2

1

1

0 VR

RV

R

RV

fbfb

If R1 = R2 = Rfb then,

210 VVV

Therefore, we can add signals with an op amp.

(Eq 8.13)

(Eq 8.12)

Example 8.3: Isolation or Voltage Follower.

Applications arise in which we wish to connect one circuit

to another without the first circuit loading the second. This

requires that we connect to a “block” that has infinite input

impedance and zero output impedance. An operational

amplifier does a good job of approximating this. Consider

the following:

The

"Block"Circuit 1 Circuit 2

+

_

+

_Vin Vout

Example 8.3 continued

Circuit 1 Circuit 2

The Block

+

_

+Vin V0_

It is easy to see that: V0 = Vin

Example 8.4: Isolation with gain.

+

_

__

+

+

20 k

Vin

Vin

V0

10 k

10 k

a

+

_

Writing a nodal equation at point “a” and simplifying gives:

inVV 20

Example 8.5: Noninverting Amplifier.

Consider the following:

R0

Rfb

V0V2_

+

+

_

a+

_

Example 8.5 continued

Writing a node equation at “a” gives;

2

0

0

0

20

02

0

2

1

,

11

0)(

VR

RV

giveswhich

RRV

R

V

so

R

VV

R

V

fb

fbfb

fb

Example 8.6: Noninverting Input.

Find V0 for the following op amp configuration.

+

_

+

+

_

_ 4 V

2 k

6 k

5 k

10 k

V0

a

Vx

Example 8.6 continued

The voltage at Vx is found to be 3 V.

+

_

+

+

_

_ 4 V

2 k

6 k

5 k

10 k

V0

a

Vxix iy

Write node equation at Vx

3

312

6

0

2

4

x

xx

xx

yx

V

VV

k

V

k

V

ii

Example 8.6 continued

Then, writing a node equation at “a” gives;

0105

0

k

)VV(

k

V xx

or

VVV x 930

Exercise 1

Find IX, VO and IO for the following op amp configuration.

Answer: IX = 0.5 mA; VO = –4 V; IO = –4/3 mA

Exercise 2

Find I and VO for the following op amp configuration.

Answer: I = 0.5 mA; VO = 4 V