MIKROE-957 mikroElektronika, MIKROE-957 Datasheet - Page 29

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MIKROE-957

Manufacturer Part Number

MIKROE-957

Description

Other Development Tools ASLK PRO ANALOG DEVELOPMENT SYSTEM

Manufacturer

mikroElektronika

Datasheet

1.MIKROE-957.pdf (104 pages)

Specifications of MIKROE-957

Rohs

yes

Product

Analog System Lab Kit PRO

Tool Is For Evaluation Of

TL082, MPY634

Operating Supply Voltage

2.5 V to 5.5 V

Description/function

Analog Lab Kit for Undergraduate Engineering

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 40 C

Current page: 29 of 104
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3.4 What should you submit

1

2

3

Analog System Lab Kit PRO

Simulate the integrator and differentiator and obtain the transient response

and phase response.

Take the plots of transient response and phase response on an oscilloscope

and compare it with simulation results.

Frequency Response - Apply a sine wave to the integrator (similarly to the

differentiator) and vary the input frequency to obtain phase and magnitude

error. Prepare a Table of the form 3.1. Figure 3.3 shows the typical frequency

response for integrators and differentiators. For an integrator, the plot shows

a phase lag which is proportional to

increasing frequency. For the differentiator, the phase will change rapidly at

natural frequency in direct proportion to quality factor. The magnitude peaks

at natural frequency and is directly proportional to the quality factor.

S. No.

S. No.

1

2

3

4

5

1

2

3

4

5

Table 3.1: Plot of Magnitude and Phase w.r.t. Input Frequency

Table 3.2: Plot of Magnitude and Phase w.r.t. Input Frequency

Input Frequency

Input Frequency

Magnitude

Magnitude

C

N

A

~

~

V

V

V

T

V

V

V

V

f

0

0

pp

p

pp

i

i

0

th

=

=

=

=

GB

=

=

1

GB s

a

b

2

b

1

1

. The magnitude decreases with

V T

1

f

p

$

+

+

+

RC

$

GB RC

GB

-

-

~

s

-

s

0

sRC

sCR

1

Q

$

sRC

+

1

+

s RC

2

+

GB

~

s

$

Phase

Phase

2

0

2

GB

l

s

k

l

4

Transient response - Apply the square wave as an input to integrator, vary

the peak amplitude of the square wave and obtain the peak to peak value

of output wave.

given by

Figure 3.4 shows sample output waveforms obtained through simulation.

S. No.

1

2

3

4

Figure 3.3: Frequency Response of integrator and differentiator

~

~

V

V

V

T

V

f

0

pp

p

pp

i

0

=

=

Peak Value of input Vp

GB

=

=

1

b

b

2

1

V T

1

f

p

$

C

~

~

V

V

V

T

+

V

V

f

+

$

RC

pp

p

pp

0

i

0

=

Table 3.3: Variation of Peak to Peak value of

GB

=

~

GB

=

-

=

is directly proportional to peak voltage of input

s

1

s

0

, where

sRC

b

Q

2

b

+

1

V T

1

f

p

$

+

+

output w.r.t. Peak value of Input

+

RC

$

s RC

2

GB

~

GB

s

-

~

$

s

-

2

0

2

s

0

sRC

~

~

V

V

V

T

Q

l

f

sRC

+

pp

p

pp

0

=

+

l

GB

=

=

s RC

1

2

GB

~

s

$

2

b

V T

1

2

0

f

2

p

$

l

,

+

RC

$

~

~

V

V

V

T

f

GB

pp

p

pp

l

-

~

0

=

being the input frequency.

GB

=

=

s

0

sRC

1

Q

Peak to Peak value of output

2

b

V T

+

1

f

p

$

+

RC

$

GB

~

s

~

2

0

2

l

s

0

Q

+

~

s

2

0

2

l

~

~

V

V

V

T

V

V

f

page 29

0

pp

p

pp

i

0

=

=

and is

GB

=

=

1

b

2

b

1

V T

1

f

p

$

+

+

RC

$

GB

-

~

s

-

s

0

sRC

Q

sRC

+

+

s R

2

GB

~

s

$

2

0

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