Download - Artificial line laboratory 7641617
Jawad Chowdhury- 7641617
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Artificial Line Laboratory
Objectives: The aim of this experiment was to be able to study the behaviour of a transmission line,
with sinusoidal and step signal input under different terminating conditions. Also to analyse the
output waves produced by the transmission line and to study there reflections, reflective co-efficient
and the effects of the different termination conditions.
By studying these different behaviours we should be able to determine the characteristic impedance
and the length of the artificial transmission line with step input signal, using the time domain
measurement technique based on the reflection concept, and with a sinusoidal excitation signal.
Background Theory:
General Information-
The artificial line that was used in the lab consists of a number of sections and was used to simulate
a length of power line spanning approximately 6000 meters. The sections were built up with
inductive elements twisted around ferrite rings to provide an inductance of 300µH and capacitors of
approximately 3500pF.
Artificial transmission lines are discrete lumped circuit elements designed to represent real
transmission lines. If it was possible to have an infinite number of circuit elements within our
artificial line then we would be able to give a perfectly accurate simulation of a long transmission
line, however this is not possible so we only have a finite number of sections with our artificial line
and this allows us to only represent a transmission line below a high frequency limit.
For our resonant condition of the artificial line is such that the reflected wave exactly opposes the
applied input waveform. Also the lowest frequency for resonance is when the line length is one
quarter of the wave length.
Reflection Co-efficient-
: Reflection Co-efficient, : Load Resistance, : Characteristic Impedance
The reflection co-efficient is a very important concept for transmission lines.
Termination Conditions-
For (short circuit)
For (open circuit)
For (Match- load resistance is same as characteristic impedance)
Impedance match is the proper termination if we don’t want any reflections.
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Characteristic Impedance-
Using KVL and KCL for a small section of the line and having the limit we arrive at
‘Telegraphers equations’:
When the equations are linked together we derived the wave equation:
The wave equation shows that the currents and voltages on the transmission line satisfy the one
dimensional wave equation.
Therefore since current satisfies the wave equation:
And current and voltage are related by equation (1), so for the general function this gives:
And since the forward waves are independent of the reverse waves we have:
Where
√
Within a constant we have:
√
is equal to the Characteristic impedance of the line.
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Length of Line-
Time Domain:
In the time domain to calculate the length of line = speed of light x wave time from input to output
Length = ( m
Frequency Domain:
To calculate the length of line we first have to find out the wave time by using the equation:
So by using this equation we get the time as:
Now that we know the time we can calculate the length of the line:
Length of line = m
Propagation Velocity-
We know that √
for the velocity of wave propagation. So we can calculate the velocity as
we know :
√
Knowing this we can calculate the transit time of the transmission line.
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Experimental Procedure-
Equipment: Agilent oscilloscope, Adjustable Frequency Signal generator, artificial line apparatus,
Digital Multi-Meter (DMM)
Part 1- Time Domain Measurement:
(a) We set the switches on the artificial line apparatus so that it produces a full element line.
We set the line termination to the open circuit setting and connected the oscilloscope to the
end of the line so we could monitor the output. The source potentiometers were then
adjusted so that the output waveform matched the input meaning there was no reflection.
We then determined the time taken for the step input signal to travel from input to output
and sketched the wave forms and estimated the time taken for reflections to travel back to
the input.
(b) Next with the load still on the open circuit setting and the source potentiometers adjusted
so as to remove any reflections of the output wave we disconnected the output and
connected one channel of the oscilloscope at the first element of the transition line. We
then drew the wave forms at the signal input and at the true input. Then we switched the
setting of the load to short circuit setting and drew the waveforms.
(c) The input signal was disconnected and the source potentiometers were measured using the
DMM.
(d) The input signal was then reconnected and the termination setting was set to variable
resistance (load) and we modified the load resistance till we found the value of termination
resistance which gave the minimum reflection at the input. The resistance was then
measured with the DMM and recorded.
Part 2- Frequency Domain Measurement:
(a) The adjustable frequency signal generator was connected up to the input and the
oscilloscope was also connected in parallel. The signal generator was set to an input signal of
5V pk-pk with 0V d.c. offset.
(b) Then the termination setting of the line was set to open circuit setting and we modified the
frequency to find the lowest frequency at which the line is resonant. Once this value was
found the DMM was used to plot the voltage distribution (pk-pk) along the line by measuring
the voltage at each signal point along the line.
(c) We then switched the termination setting to short circuit and measured the voltage
distribution along the line without changing the frequency already set.
(d) The termination setting was changed to the variable resistance and the resistance was
adjusted so that the voltage distribution at each point along the line was as uniform as
possible. By doing this the variable load resistance should be the same as the characteristic
impedance of the line. This value was then measured by the DMM and recorded.
(e) Finally we switched the setting back to the open circuit setting and recorded as many
resonant frequencies as we could.
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Results-
Part 1- Time Domain Measurement
Time events:
The time taken for the input step signal to go from input to output was . So the time taken for
the reflection to come back to the input is equal to:
Wave Forms:
1) Open Circuit setting- No Reflections
From our pictures we see that the time taken for the wave to travel from input to output in 1) is
approximately 20µs and this would mean that the time for the reflection to return to input should
equal where our reflective wave takes approximately 40µs to return to the input.
2) Signal input and the true input:
When the termination setting is set to open circuit and the reflective wave comes back after 40µs
the true input is the same as the signal input as
Time taken for signal to
travel from input to
output.
Each
interval Signal
Voltage
1) Input
signal
2) Output
signal
Input
signal
True
input
signal
Time taken for reflections
to travel back to the input
Step
Input
Time for Reflected wave
to comes back- 40µs
40µs
Start of
input signal
Start of output
signal
Start of
input signal
Start of true
input signal
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3) Signal Input and True Input- Short Circuit:
With the termination condition set to short circuit we see that the signal input wave is shown as the
reflection at the true input when the wave returns to input after 40µs as when short circuit setting
.
–
In the time domain in part 1 of our experiment we measured the source potentiometer using the
DMM to get the resistance, we then set the termination setting to variable resistance (load) and we
then changed the value of the termination resistance until we got minimum reflection at the input.
Once we got this we took the measurement of the resistance using the DMM.
40µs
Start of
input signal
Start of true
input signal
Time taken for
input signal to be
reflected and return
back to input
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0
2
4
6
8
10
12
0 5 10 15 20 25
Vo
ltag
e p
k-p
k (V
)
Section
Open Circuit Voltage Distribution
Part 2- Frequency Domain Measurement-
Resonant Frequency-
We set the termination setting to open circuit setting and then modified the frequency till we found
the lowest value at which the line is resonant.
Lowest Resonant Frequency- 13.96 kHz
Voltage Distribution (pk-pk) for open circuit at lowest resonant Frequency
Section
Voltage- Open Circuit (V)
0 0.073
1 0.791
2 1.533
3 2.277
4 3.01
5 3.718
6 4.41
7 5.086
8 5.724
9 6.327
10 6.895
11 7.415
12 7.907
13 8.34
14 8.691
15 8.983
16 9.226
17 9.414
18 9.55
19 9.635
20 9.66
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0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
2
0 5 10 15 20 25
Vo
ltag
e p
k-p
k (V
)
Section
Short Circuit Voltage Distribution
Voltage Distribution (pk-pk) for Short Circuit at lowest resonant Frequency
Section
Voltage- Short Circuit (V)
0 1.826
1 1.814
2 1.792
3 1.76
4 1.718
5 1.666
6 1.605
7 1.534
8 1.455
9 1.367
10 1.271
11 1.171
12 1.067
13 0.955
14 0.826
15 0.696
16 0.561
17 0.427
18 0.292
19 0.151
20 0.021
Value for for Frequency Domain Measurement
The termination setting was set to variable resistance (load) and the resistance was adjusted so that
the voltage distribution across each section was the same. The value measured was:
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Other Resonant Frequencies
The termination setting was set once again to open circuit setting and we then used the oscilloscope
to see the other resonant frequencies by varying the frequency. From our experiment we saw that it
was quite difficult to see the value all the time as the wave was so small and also the equipment we
used was not sensitive enough to be able to increase the frequency by a small amount once you
reached a high number therefore you are unable to see all the values. However we noticed there
was a pattern and the resonant frequency was linear so the same value increased each time would
give a line that was resonant.
Resonant Frequencies (kHz)
44.3
69.0
98.1
126.5
145.9
172.9
The resonant Frequencies occur at each interval of approximately 27 kHz.
Data Analysis and Discussion-
Part1:
Explanation of waveforms:
1) In part 1 for our First waveform we set the termination condition to open circuit and connected a
signal at the input and had a connection at the output to see the output wave compared to the
input. Once we saw the output wave we modified the value of till we had an output wave that
matched the input so that it had no reflections.
The output wave starts after 20µs as that is the time taken to go from input to output.
The value of remained the same through out the rest of the measurements in part 1.
2) For our second condition the termination setting remained as open circuit. However we
disconnected the channel from the output and connected it to the true input to see the true input
wave form. We see that there is no reflection at the true input. The reason for this can be explained
using the equation for the reflection co-efficient:
When the circuit is set to the open circuit setting the value for is very large, ideally the value for
will be infinite, and the value for is very small, negligible, therefore the value for the reflection
co-efficient so when the signal is multiplied by the reflection co-efficient when the signal
returns to the input we see that the true input signal is almost identical to the input with no
reflection. We also see that the true input wave starts after 40µs as that is the time taken for the
reflection to come back to the input.
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3) For our third condition the termination setting is set to short circuit setting. We see that the true
input is a reflection of the input. This can also be explained using the equation for the reflection co-
efficient.
While in short circuit setting the value for is very small, ideally 0, and therefore making the value
for
= -1. So as the value for the reflection co-efficient the wave we see at the true
input will be multiplied by the value and therefore give us a wave that is a reflection of the input at
the true input. That is why we see a reflection.
Also the reflection wave at the true input begins after 40µs as that is the time it takes for the
reflected wave to come back to the input.
Explanation why
In part 1 when we took measurements of the source resistance we saw that it was not the same
value as the load resistance . The values we got were not the same as there is impedance in the
oscilloscope and in the wires which caused the values not to be the same. Also the reflections
caused by the load resistance are visible on the input signal; where as the reflections caused by the
source resistance are visible on the output signal. This means we can’t match them identically and
therefore there would be a difference between the output and input causing the values of
not to be the same. However the values were not far off each other.
Part 2-
Short circuit like behaviour at resonance-
When the line is resonant the inductance and capacitance are equal so they cancel each other out
causing the circuit to behave as if it was short circuit.
Comparison between resistance values taken in parts 1 and 2
The value we measured for in part 1 is very close to the value for measured in part 2,
but not exact. The value would not be exact because of impedance in the circuit and other losses but
the value from part 2 is very close to the values from part 1.
Part1: Part2:
All the values are quite similar to each other.
Analysis of the length of line
Already in the report I have analysed the length of line by calculating the length of the line in the
time domain and the length of line in the frequency domain.
In the time domain we calculated the length to be 6000m and in the frequency domain we
calculated it to be 5373m.
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We can also use another method to calculate the transit time of the line and also its length. We can
do this by using the propagation velocity. We previously in the report calculated the propagation
velocity to be . We also know that there are 21 sections on the artificial line
that we used, so we can use both these values to calculate the transit time:
So the value we have calculated for the transit time . Using this value we can calculate
the maximum length of the real transmission line the apparatus we used simulated:
m
So the maximum length of line of the real transmission line this apparatus represents is 6450m. This
value is similar to the values calculated in the frequency and time domain.
Why at resonant frequency amplitude of the input goes down to almost zero?
At resonant frequency the amplitude of the input almost goes down to zero as the impedance of the
line is the same and the reflected wave cancels out the input making it almost zero as the reflected
wave has the same magnitude and phase as the forward wave.
Relationship between Resonant Frequencies
The values we got for the resonant frequencies showed a pattern, in the table under other resonant
frequencies, where it increased every 27 kHz approximately. The lowest resonant frequency we
measured was 13.96 kHz. So as the values increased at every 27kHz we saw that the relationship
between the resonant frequencies was that:
So if you follow this pattern you can calculate every resonant frequency of the line.
Conclusion-
After performing this experiment and completing this report I believe this artificial line experiment is
a very helpful and useful experiment in understanding transmission lines in the way they work and
the fundamental concepts about them. This experiment is very important in understanding
transmission lines as it allows you to have a practical experience with them as well as seeing and
being able to understand the different functions and why transmission lines are so important in our
everyday life. Also by performing this experiment it gave me good understanding of transmission
lines and why they work in the way they do.
This experiment shows how the different functions of a transmission line works in open circuit, short
circuit and variable resistance termination setting. Also how the transmission line can work in the
time domain and the frequency domain. It also shows the effects of resonance on the line and how
the line has different resonant frequencies. Furthermore it allowed us to see the different ways we
can determine the length of the line and also how to calculate the propagation velocity. We were
able to see how the equations we have learnt are practically used.
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In conclusion I believe the artificial line experiment is a very good experiment and is fundamental in
being able to understand and to see how a transmission line actually works. Being able to see how it
works is what makes the experiment so useful and helpful in the understanding of transmission
lines.
Reference-
Lab Manual