Chapter 7 Delta Modulator - elektro.undip.ac.idelektro.undip.ac.id/sukiswo/?download=PT2_7_Delta...

Chapter 7

Delta Modulator

Chapter 7 – DELTA MODULATOR

7-1: Curriculum Objectives

1. To understand the theory of delta modulation.

2. To understand the signal waveforms of delta modulation.

3. Design and implementation of delta modulator.

4. Measurement and adjustment of delta modulator.

7-2: Curriculum Theory

1. The Operation Theory of Delta Modulation

Delta modulation is a kind of source coding which can convert the analog signal to digital signal.

After that we can deal with the digital signal easily such as encoding, filtering the unwanted

signal and so on.Furthermore, the transmission quality of digital signal is better than analog signal,

this is because digital signal can recover the original signal easily by the comparator.

The block diagram of delta modulator is shown in figure 7-1. From figure 7-1, the subtraction

between the low frequency signal x(t) and the signal xs(t) will produce a difference signal

d(t) , where xs(t) is a reference signal, which is the former sampling value. Therefore the

expression of the difference signal d(t) is given as

However the difference signal d(t) will be converted by a limiter, then we can obtain a signal Δ(t)

given as

Figure 7-1 Block diagram of delta modulator.

Hence, we know that if the difference signal d(t) is larger than zero, this means that the reference

signal xs (t) is lower than the low frequency signal x(t), i.e. the estimated value is too small and we

need to increase the next estimated value by Δ, on the other words, we only need to send a

variation value, which is Δ during the transmission. Nevertheless, if the difference signal d(t) is lower

than zero, then we only need to transmit a variation value, which is - Δ.

Thus it can be seen that every sampling value is related to the former sampling value, therefore, we

can estimate the next sampling value base on the former sampling value. Then we only need to

concentrate on the t ransmission of the estimated value and need not care about the

quantification encode, so this situation can greatly save the transmission bandwidth. As for PCM

modulation, every sampling value is independently and need to be quantified for encoding, thus, this

situation will increase transmission bandwidth. For example, if the PCM signal after encoded is 8 bits,

then the transmission bandwidth will be BT≥ 8fs / 2 = 4fs = 8 W , which is 8 times more than

the original bandwidth. Although PCM modulation increases the quality of transmission, it also

increases the transmission bandwidth. However delta modulation can reduce the

transmission bandwidth and achieve the quality of transmission as PCM modulation.

Assume the sampling signal be

After the signal Δ(t) is sampled, we can obtain the expression of delta modulation signal as

Finally we integrate the delta modulation signal to take as the next reference signal x, (t) of delta

modulation signal. The expression is given as

Although delta modulation has the advantages of simple structure and small transmission bandwidth,

it also has the disadvantage of slope overload. As a result of delta modulation is the capacity of the

variation Δ in the T, region, therefore the maximum slope of the delta modulation is Δ / T, = f Δ. If

the maximum slope of the input signal exceeds Δ / T, = fsΔ, that means the step size is too small,

then slope overload will occur in the delta modulation. Consequently the slope of the input

signal must satisfies the prerequisite condition of delta modulation, which is given as follow

Slope overload will cause the modulation signal changes cannot follow closely enough to the

input signal, and then the recovery of the original signal will become distorted. In order to prevent

slope overload, we notice that from equation (7-6), the slope of the input signal cannot be too high

and we can also increase the values of fs or Δ.

2. Implementation of Delta Modulator

Figure 7-2 is the basic circuit diagram of delta modulation. The audio signal will pass through a low-

pass filter to remove the unwanted signals, which can prevent the interference from noise. The

comparator is to compare the audio signal and the output signal of integrator, then the difference

will be sampled by the D-type flip-flop and the output signal is a TTL digital signal. After that the

output signal will feedback to integrator for integration and the output signal of integrator will again

compare to the input signal to obtain the value of Δ or – Δ.

We modified the circuit diagram of delta modulation in figure 7-2 to figure 7-3. From figure 7-3, we

add a multiplexer to control the gain of the integrator. This is because the gain of the integrator will

affect the slope of the output signal of integrator, therefore, this method can prevent the

occurrence from slope overload. U1 is the comparator, which can compare the audio signal and the

output signal of integrator, then the output square wave signal will be sampled by a D-type flip-flop

and finally the output signal is the delta modulation signal. U2 is the conversion of unipolar to

bipolar circuit. Since there is no output signal from integrator by inputting the unipolar square wave

signal, therefore, we need to convert the unipolar signal to bipolar signal. Analog switch is a structure

of multiplexer. The purpose of the analog switch is the selection of the amplified gain of

integrator. When AB=00, the signal will pass through R14, R13, R12, R11 and send into

integrator; when AB= 11, the signal will pass through R14 to integrator. U3 is an inverse integrator.

The expression without R16is given as

By adding a shunt resistor R16 between integrator U3 and capacitor C1, we can improve the low

frequency response of the integrator. Assume that R16 and C1 are equivalent impedance, then we get

where

Figure 7-2 Basic circuit diagram of delta modulator.

Figure 7-3 Circuit diagram of delta modulator.

7-3: Experiment Items

Experiment 1: Delta modulator

1. To implement a delta modulator circuit as shown in figure 7-3 or refer to figure DCT7-1 on

GOTT DCT-6000-04 module.

2. Let J2 and J3 be short circuit, i.e. the connection between X0 and X is on. At the signal input

port (I/P1), input a 2 V amplitude and 500 Hz sine wave frequency. Next at the CLK input port

(I/P2), input a 5 V amplitude and 32 kHz TTL signal. Then observe the input signal (T1), the

output port of comparator (T2), the output port of the conversion from unipolar to bipolar (T3),

the output port of tunable gain (T4), the output port of integrator (T5) and the output port of

delta modulation signal (O/P) by using oscilloscope. Finally record the measured results in table

7-1.

3. According to the input signals in table 7-1, repeat step 2 and record the measured results in table

7-1.

4. Let J2 and J4 be short circuit, i.e. the connection between X1 and X is on. At the signal input

port (I/P1), input a 2 V amplitude and 1 kHz sine wave frequency. Next at the CLK input port

(I/P2), input a 5 V amplitude and 64 kHz TTL signal. Then by using oscilloscope, observe

on the output signal waveforms of T1, T2, T3, T4, T5 and O/P signal. Finally record the

measured results in table 7-2.


7-2.

6. Let J1 and J3 be short circuit, i.e. the connection between X2 and X ison. At the signal input port

(I/P1), input a 2 V amplitude and 1.5 kHz sine wave frequency. Next at the CLK input port (I/P2),

input a 5 V amplitude and 128 kHz TTL signal. Then by using oscilloscope, observe on the

output signal waveforms of T1, T2, T3, T4, T5 and O/P signal. Finally record the measured

results in table 7-3.


7-3.

8. Let J1 and J4 be short circuit, i.e. the connection between X3 and X ison. At the signal input port

(I/P1), input a 2 V amplitude and 2 kHz sine wave frequency. Next at the CLK input port (I/P2),

input a 5 V amplitude and 256 kHz TTL signal. Then by using oscilloscope, observe on the

output signal waveforms of T1, T2, T3, T4, T5 and O/P signal. Finally record the measured

results in table 7-4.


7-4.

7-4: Measured Results

Table 7-1 Measured results of delta modulation with 32 kHz CLK signal.

Input Signals Measured Results

500 Hz

2V

T1 T2

T3 T4

T5 DM O/P

Table 7-1 Measured results of delta modulation with 32 kHz CLK signal (Continue).


1 kHz

2V

T1 T2

T3 T4

T5 DM O/P



2 kHz

2 V

T1 T2

T3 T4

T5 T6



3 kHz

2V

T1 T2

T3 T4

T5 DM O/P



1 kHz

2V

T1 T2

T3 T4

T5 DM O/P



2 kHz

2 V

T1 T2

T3 T4

T5 DM O/P

Table 7-2 Measured results of modulation with 64 kHz CLK signal (Continue).


3 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



4 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



1.5 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



3 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



5 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



7 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



2 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



4 kHz

2 V

T1 T2

T3 T4

T5 DM O/P

Table 7-4 Measured result of delta modulation with 256 kHz CLK signal (Continue).


6 kHz

2 V

T1 T2

T3 T4

T5 DM O/P



8 kHz

2 V

T1 T2

T3 T4

T5 DM O/P

7-5: Problems Discussion

1. Try to sketch the block diagram of delta modulation.

2. Explain the purposes of comparator and conversion of unipolar to bipolar in figure 7-2.

Why?

3. Explain the purposes of analog switch in figure 7-3.

4. If the signal of CLK in figure 7-3 is not TTL signal, then describe what will the outputbe.

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