06 The Oscilloscope Lab Report
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Apr 26, 2024
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PHY 2092 Sect. 5
06 The Oscilloscope
Author: Jaidyn Lodens
Date of Experiment: 2 / 14 / 2024
Date of Report: 4 / 1 / 2024
Partners: Christian Gonzalez
GSA: Syed Hasan
1
Introduction
The purpose of this lab was to understand how an oscilloscope works. In this lab, a D.C. power
supply and a signal generator are used to create different waveforms. Data about these
waveforms are then collected and compared to the picture that was created using the
oscilloscope. The lab helps demonstrate how to use the oscilloscope, how different power
supplies create different waveforms, how voltage and current affect waveforms, and how waves
can be added together to create new waveforms.
Data
06 The Oscilloscope Datasheet
Discussion
Part 1 Step 2:
2
Part 1 Step 7:
Part 1 Step 8:
It changes the specific horizontal points on the graph.
Part 2 Step 1:
The natural sine wave is the most accurate to what the wave truly looks like compared to the
triangle and square waves. It may be easier and more accurate to measure the peak-to-peak
voltage using a triangle wave since the peak is easily determined in this form.
Part 2 Step 2:
The changes on the VOLT / DIV knobs and TIME / DIV knobs change in larger or smaller
increments based on if the VARIABLE knobs are in the CAL’D position. They change the height
of the wave.
Part 3 Step 1:
In the first setup, the 267 resistor measured 8.5 volts, and the 500 resistor measured 5 volts. In
the second setup, the 500 resistor measured 9 volts, and the 267 resistor measured 4.5 volts.
The voltage changed because of the order of the resistors, but the total voltage remained the
same. Since the total voltage was the same, it is giving results that would be similar to a D.C.
power supply.
Part 3 Step 2:
The phase relationship between voltage and current is ideally a zero phase shift. No matter
what, as the voltage moves in the positive alternating direction, the current will also move in the
positive alternating direction. Same for when the voltage moves in the negative direction.
3
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Related Questions
The waveform displayed on an oscilloscope is as shown in Figure The 'time/cm' switch is set to 1 ms/cm, and
the 'volts/cm' switch is set to 1 V/cm. Determine the (i) amplitude of waveform Q, (ii) peak to peak value of
waveform P, (iii) frequency of waveform P and (iv) phase angle difference between P and Q in Degrees.
P
Upload your Answers steps in the "Final Answer Submission" Link provided in the Moodle.
(i) Amplitude of waveform Q =
(ii) Peak to peak value of waveform P =
(iii) Frequency of waveform P =
(iv) Phase angle difference between P and Q in Degrees =
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ii) A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on 2ms/cm and
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Peak height of waveform G and H are 4.6 cm and 6.7 cm respectively. The difference between the two
waveforms is 0.2. Determine
a) Frequency,
b) Phase difference,
c) RMS value of G waveform.
a) frequency
b) phase difference
c) RMS value of G waveform
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3. A sinusoidal waveform displayed on an oscilloscope is shown in Figure 2. The 'time/cm' switch is on 10
ms and the 'volts/cm' switch is on 5V/cm. Determine for the waveform:
a) The frequency of both waveforms
b) The peak-to-peak value of waveform Q
c) The amplitude of waveform P
Figure 2
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Note: Please do not handwriting
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waveform P, (111) frequency of waveform P and (iv) phase angle difference between P and Q in Degrees.
主
Upload your Answers steps in the "Final Answer Submission" Link provided in the Moodle
(i) Amplitude of waveform Q =
(ii) Peak to peak value of waveform P
(iii) Frequency of waveform P =
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d) The r.m.s. value of waveform Q
e) The phase difference of waveform Q relative to waveform P
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A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on
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the waveform. The Peak to Peak height of waveform G and H are 4.8 cm and 5.3 cm
respectively. The difference between the two waveforms is 0.5. Determine
a) frequency;
b) phase difference,
C) RMS value of G waveform
d) peak value of H waveform
a) frequency
b) phase difference
C) RMS value of G waveform
d)peak value of H waveform
(8)
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The waveform displayed on an oscilloscope is as shown in Figure 3. The 'time/cm' switch is set to 2
ms/cm, and the 'volts/cm' switch is set to 0.5 V/cm. Determine:
(i) amplitude of waveform Q
(ii) peak to peak value of waveform P
P
(iii) frequency of waveform P
(iv) angular frequency of waveform Q and
(v) phase angle difference between P and
Q in Degrees.
主
24°C
Type here to search
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A sinusoidal waveform displayed on an oscilloscope is shown in Figure 2. The 'time/cm' switch is on 10
ms and the 'volts/cm' switch is on 5V/cm. Determine for the waveform:
a) The frequency of both waveforms
b) The peak-to-peak value of waveform Q
c) The amplitude of waveform P
d) The r.m.s. value of waveform Q
e) The phase difference of waveform Q relative to waveform P
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An oscilloscope has its volts/cm knob set at 0.2v/cm and its time /cm knob set at 0.2millisec/cm. If the AC waveform on the screen had a height = 8.4cm and a width = 2.6cm, solve the following:a. The frequency of the waveform b. The peak voltage
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A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on 40 ms/cm and the volt/cm switch on 4 V/cm. The width of each complete cycle is 6.8 cm for both the waveform. The Peak to Peak height of waveform G and H are 5.5 cm and 5.3 cm respectively. The difference between the two waveform is 0.8. Determine
a) Frequency,
b) Phase difference,
c) Peak value value of G waveform.
c) RMS value of H waveform.
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A double beam oscilloscope displays 2 square waveform G and H.
The time/cm switch is on 45 ms/cm and the volt/cm switch on
5V/cm. The width of each complete cycle is 6.8 cm for both the
waveform. The Peak to Peak height of waveform G and H are 4.6
cm and 4.9 cm respectively. The difference between the two
waveforms is 0.9. Determine
a) frequency,
b) phase difference,
c) peak value of H waveform.
d) RMS value of G waveform
a) frequency
b) phase difference
C) Peak value of H waveform
d) RMS value of G waveform
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A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on 2 ms/cm and the volt/cm switch on 4 V/cm. The width of each complete cycle is
5.9 cm for both the waveform. The Peak to Peak height of waveform Gand H are 5.6 cm and 5.9 cm respectively. The difference between the two waveform is 1.1. Determine
a) frequency,
b) phase difference,
C) RMS value of G waveform
d) peak value of H waveform
a) frequency
b) phase difference
C) RMS value of G waveform
d)peak value of H waveform
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A double beam oscilloscope displays 2
square waveform G and H. The time/cm
switch is on 2ms/cm and the volt/cm switch
on 4 V/cm. The width of each complete cycle
is 5.3 cm for both the waveform. The Peak to
Peak height of waveform G and H are 5.5 cm
and 5.9 cm respectively. The difference
between the two waveforms is 0.9.
Determine
a) frequency,
b) phase difference, (1Mark)
c) RMS value of G waveform (1
a) frequency
b) phase difference
c) RMS value of G waveform
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A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on 50 ms/cm and the volt/cm switch on 6 V/cm. The width of each complete cycle is 6.8 cm for both the waveform. The Peak to Peak height of waveform G and H are 4.5 cm and 5.5 cm respectively. The difference between the two waveforms is 0.2. Determine
a) Frequency
b) Phase difference
c) RMS value of G waveform
d) Peak value of H waveform
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3. A double beam oscilloscope displays 2 sine waveforms A and B. The time/cm
switch is on 100us/cm and the volt/cm switch on 2V/cm. The width of each
complete cycle is 6 cm for both the waveforms. The height of waveforms A and
B are 3 cm and 3.5cm respectively. Determine their a) frequency, b) phase
difference, and c) peak and r.m.s value of voltages. The difference between the
two waveforms is 0.6 cm.
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Please Connect the circuit shown above in Tinkercad and measure the output voltage in oscilloscope.
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A double beam oscilloscope displays 2 square waveform G and H. The time/cm switch is on 2ms/cm and the volt/cm
switch on 4 V/cm. The width of each complete cycle is 5.9 cm for both the waveform. The Peak to Peak height of
waveform G and H are 4.2 cm and 4.5 cm respectively. The difference between the two waveforms is 0.6. Determine
a) frequency, (r
b) phase difference, (
c) RMS value of G waveform
d) peak value of H waveform (
a) frequency
b) phase difference
C) RMS value of G waveform
d)peak value of H waveform
The instrument which disnlay the numorical unlun of th
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Identify which measurement this oscilloscope time difference reading is useful for.
Oscilloscope-XSC1
Time
250.000 us
1.261 ms
Channel_A
169.064 V
168.513 V
-550. 584 mV
Channel_B
89. 282 V
95.005 V
5.722 V
Reverse
T2-T1
1.011 ms
Save
Ext. trigger
Timebase
Scale: 200 us/Div : Scale: 100 V/Div
X pos. (Div): 0
Channel A
Channel B
Scale: 100 V/Div
Y pos. (Div): 0
Trigger
Edge: F
Level: 0
A B Ext
Y pos. (Div): 0
V
Y/T Add B/A
A/B
AC
DC
AC
DC
Single Normal
O period
O none of the above
O phase shift
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Discussion
1. It is required to draw a sine wave signal of amplitude 12 volts P.P and frequency of 2 KHz
on oscilloscope having voltage scale of 2 volts/cm and time base scale of 0.125 m sec / cm.
Draw it on your lab paper.
2. It is required to draw a sine wave signal of amplitude 8 volts P.P and frequency of 2 KHz on
ocilloscope having voltage scale of 2 volts/cm and time base scale of 0.125 u sec / cm.
Draw it on your lab paper.
3. It is required to draw a sine wave signal of amplitude 4 volts P.P and frequency of 1 KHz on
oscilloscope having voltage scale of 2 volts/cm and time base scale of 1 um sec / cm. Draw it
on your lab paper.
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One cycle of a square wave signal observed on an oscilloscope is found to
occupy 6 cm at a scale setting of 30 µs/cm. What is the signal frequency?
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Pre-Laboratory Assignment
1-) What are the basic purposes of using an oscilloscope and a multimeter?
2-) What is the difference between AC and DC coupling?
3-) What is the purpose of the trigger systemin the oscilloscope?
4-) Draw the following signals:
a-) 5 sin 2n1000t
b-) 3cos2n500t +3
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27)
For the Double beam oscilloscope shown in Figure. Determine (i) the magnitude of pulse for waveform A and B, (ii) Time period of waveform A and B and (iii) Frequency of waveform A. The time/cm switch for waveform A is on 35 μs/cm, time/cm switch for waveform B is on 85μs/cm, the volts/cm switch for waveform A is on 35 V/cm and the volts/cm switch for waveform B is on 25 V/cm.
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