MIKROE-957 mikroElektronika, MIKROE-957 Datasheet - Page 72

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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

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14.1 Brief theory and motivation

In Experiment 6, we used an analog multiplier in conjunction with an integrator to

build a VCO. In this experiment, we will use a multiplying DAC7821 (instead of a

multiplier) and an integrator to implement a digitally controlled square and triangular

wave generator. See Figure 14.1 for the circuit schematic of a digitally programmable

square and triangular wave generator. VOUT is the square wave output and the

output of the integrator is the triangular waveform.

Frequency of oscillations of digital programmable oscillator is given by

page 72

To design a digitally controlled oscillators where the oscillation frequency of

the output square and triangular wave forms is controlled by a binary pattern.

Such systems are useful in digital PLL and in FSK generation in a MODEM.

TL082

C 1u

Goal of the experiment

Figure 14.1: Circuit for Digital Controlled Oscillator

R 1k

Q

f

=

=

4

10

RC

1

R1

TL082

TL082

$

R2

b

1

+

R

R

2

1

l

C

I

I

OUT1

OUT2

$

1

/

11

0

4096

DAC7821

A

R

V

n

FB

OUT

2

n

GND

V

V

V

DD

DD

REF

14.2 Specifications

Design a Digitally Programmable Oscillator that can generate square and triangular

waveforms with a maximum frequency of 400 Hz.

14.3 Measurements to be taken

Implement the Digitally programmable Square and Triangular wave generator using

the circuit as shown in Figure 14.1.Observe the frequency of Oscillations of system

and vary it by varying bit pattern input to the DAC.

14.4 What Should you Submit

1

2

3

Simulate the circuit using any simulator and observe the frequency of oscillation

of the square and triangular waveforms. See Figure 14.2 for the result of

simulation. The typical simulation waveforms are of the form shown in Figure

14.3. For this simulation, we used the macro-model of MV95308 since the

macro-model for the DAC is not available at the time of writing.

Vary the bit pattern input to the DAC in manner specified in Table 14.1 and

note down the change in the frequency of oscillations and compare the

practical results with the simulation results.

Plot a graph where the x-axis shows the analog equivalent of the bit pattern

and the y-axis shows the frequency of oscillations. Note that the 12-bit input

to the DAC is interpreted as an unsigned number.

S.No.

1

2

3

4

Table 14.1: Varying the bit pattern input to the DAC

100000000000

010000000000

001000000000

000100000000

BIT Pattern

Peak to Peak Amplitude of the output

Analog System Lab Kit PRO

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