Difference between revisions of "ExpEYES/C3/Characteristics-of-Sound-Waves/English-timed"

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|00:08
 
|00:08
 
| In this tutorial, we will learn to demonstrate:
 
| In this tutorial, we will learn to demonstrate:
 +
How to generate a sound wave,
 +
frequency response of a sound source,
  
* How to generate a sound wave
+
how to calculate velocity of sound,
 
+
'''interference''' and '''beats''' of sound waves,
* Frequency response of a sound source
+
 
+
forced oscillations of a sound source.
* How to calculate velocity of sound  
+
 
+
* '''Interference''' and '''Beats''' of sound waves  
+
 
+
* Forced oscillations of a sound source.
+
  
 
|-
 
|-
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|And, show:
 
|And, show:
  
* '''Xmgrace plot'''s  
+
'''Xmgrace plot'''s,
  
* '''Fourier Transforms''' and  
+
'''Fourier Transforms''' and  
  
* '''Circuit diagram'''s for our experiments.
+
'''Circuit diagram'''s for our experiments.
  
 
|-
 
|-
 
|00:38
 
|00:38
 
| Here, I am using:
 
| Here, I am using:
* '''ExpEYES''' version '''3.1.0'''
+
'''ExpEYES''' version 3.1.0,
* '''Ubuntu Linux''' OS version '''14.10'''.
+
'''Ubuntu Linux OS''' version 14.10.
  
 
|-
 
|-
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|-
 
|-
 
|02:40
 
|02:40
| Drag the '''mSec/div''' slider to set in '''compressions''' and '''rear-fractions'''.
+
| Drag the '''mSec/div''' slider to set in '''compressions''' and '''rarefactions'''.
  
 
|-
 
|-
 
|02:48
 
|02:48
| Click on '''CH2 '''and drag to '''FIT'''. Voltage and frequency of '''SQ1''' is displayed on the right-side.
+
| Click on '''CH2 '''and drag to '''FIT'''. Voltage and frequency of '''SQ1''' are displayed on the right-side.
  
 
|-
 
|-
 
|02:59
 
|02:59
| Move the '''frequency''' slider to set in '''sound waves'''.
+
| Move the frequency slider to set in sound waves.
  
 
|-
 
|-
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|-
 
|-
 
|05:16
 
|05:16
|From the various '''Phase''' values, we will use ''178deg'' and ''106deg'' to calculate velocity of sound.
+
|From the various '''Phase''' values, we will use ''178 deg'' and ''106 deg'' to calculate the velocity of sound.
  
 
|-
 
|-
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|06:09
 
|06:09
 
| Now, we will demonstrate:
 
| Now, we will demonstrate:
* '''Interference'''
+
'''Interference''',
  
* '''Beats'''  
+
'''Beats''',
  
* '''Xmgrace plot''' and  
+
'''Xmgrace plot''' and  
  
* '''Fourier Transform''' of the two sources of sound.
+
'''Fourier Transform''' of the two sources of sound.
  
 
|-
 
|-
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|make sure that you have installed:
 
|make sure that you have installed:
  
* '''python-imaging-tk'''
+
'''python-imaging-tk''',
  
* '''grace'''
+
'''grace''',
  
* '''scipy''' and
+
'''scipy''' and
  
* '''python-pygrace''' on your system.
+
'''python-pygrace''' on your system.
  
 
|-
 
|-
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|09:36
 
|09:36
 
|In this tutorial, we have learnt to demonstrate:
 
|In this tutorial, we have learnt to demonstrate:
 +
how to generate a sound wave,
  
* How to generate a sound wave
+
'''Frequency response''' of a sound source,
 
+
* '''Frequency response''' of a sound source  
+
  
* How to calculate velocity of sound waves
+
how to calculate velocity of sound waves,
  
* '''Interference''' and '''Beat''' pattern of sound waves  
+
'''Interference''' and '''Beat''' pattern of sound waves,
  
* '''Forced oscillations''' of sound source.  
+
'''forced oscillations''' of sound source.  
  
 
|-
 
|-
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|And, have shown:
 
|And, have shown:
  
* '''Xmgrace plot'''s  
+
'''Xmgrace plot'''s,
  
* '''Fourier Transforms''' and  
+
'''Fourier Transforms''' and  
  
* '''Circuit diagrams''' for our experiments.
+
'''Circuit diagrams''' for our experiments.
  
 
|-
 
|-
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|As an Assignment-  
 
|As an Assignment-  
  
* Capture a '''sound burst'''  
+
Capture a '''sound burst'''  
  
 
Hint: A bell or a clap can be used as source of sound. This is the circuit diagram.
 
Hint: A bell or a clap can be used as source of sound. This is the circuit diagram.

Latest revision as of 09:06, 22 September 2017

Time Narration
00:01 Hello everyone. Welcome to this tutorial on Characteristics of Sound Waves.
00:08 In this tutorial, we will learn to demonstrate:

How to generate a sound wave, frequency response of a sound source,

how to calculate velocity of sound, interference and beats of sound waves,

forced oscillations of a sound source.

00:29 And, show:

Xmgrace plots,

Fourier Transforms and

Circuit diagrams for our experiments.

00:38 Here, I am using:

ExpEYES version 3.1.0, Ubuntu Linux OS version 14.10.

00:49 To follow this tutorial, you should be familiar with ExpEYES Junior interface. If not, for relevant tutorials, please visit our website.
01:01 Let's first begin with definition of sound.

Sound is a vibration that propagates as an audible mechanical wave of pressure & displacement.

01:13 It requires a medium to propagate. The medium can be air, water or any metal surface.
01:22 In this tutorial, we will carry out various experiments to show characteristics of sound waves.
01:30 Let's perform an experiment to show frequency of sound waves.
01:35 In this experiment, ground(GND) is connected to Piezo buzzer (PIEZO).

Piezo buzzer (PIEZO) is connected to SQR1.

01:44 Microphone (MIC) is connected to A1. Here, Piezo buzzer(PIEZO) is a source of sound.

This is the circuit diagram.

01:55 Let's see the result on the Plot window.
01:59 On the Plot window, under Setting Square waves, set the frequency as 3500Hz.
02:07 Click on SQR1 check-box. Frequency of SQR1 is set to 3500Hz. A digitized sound wave is generated.
02:20 Move the frequency slider to change the waveform.
02:27 Click on SQ1 and drag to CH2. Input data of SQ1 is assigned to CH2. A square wave is generated.
02:40 Drag the mSec/div slider to set in compressions and rarefactions.
02:48 Click on CH2 and drag to FIT. Voltage and frequency of SQ1 are displayed on the right-side.
02:59 Move the frequency slider to set in sound waves.
03:04 Sound wave produced by the Piezo buzzer is shown in black colour.
03:10 Amplitude of the wave changes as Piezo buzzer is moved closer and away from the MIC respectively.
03:19 Now, we will demonstrate frequency response of Piezo buzzer.
03:24 On the Plot window click on EXPERIMENTS button. Select Experiment list opens. Click on Frequency Response from the list.
03:39 Two new windows Audio Frequency response Curve and Schematic open. Schematic window shows the circuit diagram of the experiment.
03:52 On the Audio Frequency response Curve window, click on START button.
03:59 Frequency response of the Piezo buzzer is set in. Frequency response has maximum amplitude at 3700Hz.
04:11 On the same window, click on Grace button. Grace window opens showing Frequency response Curve.
04:22 Now, we will measure velocity of the source of sound.
04:27 On the Plot window, click on EXPERIMENTS button.

Select Experiment list opens. Click on Velocity of Sound from the list.

04:41 Two new windows EYES Junior: Velocity of Sound and Schematic open. Schematic window shows the circuit diagram of the experiment.
04:55 On EYES Junior: Velocity of Sound window, click on Measure Phase button.
05:02 We can obtain different Phase values by changing the distance between MIC and Piezo buzzer.
05:11 Click Measure Phase button to obtain different Phase values.
05:16 From the various Phase values, we will use 178 deg and 106 deg to calculate the velocity of sound.
05:28 We can obtain these values when Piezo is kept close and 2cm away from the MIC.
05:37 To obtain accurate results, ensure that MIC and Piezo buzzer are placed on the same axis.
05:45 To calculate the value of velocity of sound, we have the formula as shown.

Velocity of sound obtained from the experiment is 350m/sec.

05:59 As an assignment, calculate the value of wavelength of sound. Formula: λ= v/f(Lambda = v upon f).
06:09 Now, we will demonstrate:

Interference,

Beats,

Xmgrace plot and

Fourier Transform of the two sources of sound.

06:20 To show Grace plots in the experiments,
06:23 make sure that you have installed:

python-imaging-tk,

grace,

scipy and

python-pygrace on your system.

06:34 In this experiment, we use two Piezo buzzers as source of sound.
06:41 In this experiment, Piezo 1 is connected to SQR1 and ground(GND). Piezo 2 is connected to SQR2 and ground(GND). This is the circuit diagram.
06:56 Let's see the result on the Plot window.
07:00 On the Plot window, set frequency as 3500Hz.
07:06 Click on SQR1 and SQR2 check-boxes. Frequency of SQR1 and SQR2 is set to “3500Hz”.
07:20 A digitized sound wave is generated.
07:24 Move the frequency slider to change the waveform.
07:29 Click on EXPERIMENTS button and select Interference of Sound. EYES: Interference of Sound window opens.
07:39 At the bottom of the window, change NS, that is, number of samples value to 1000.
07:48 Click on SQR1 and SQR2 check-boxes. Click on START button. Interference pattern is seen.
08:00 Now, click on Xmgrace button. A new window opens with a Grace pattern.
08:08 Now, we will show Beats pattern.
08:11 Click on EXPERIMENTS button and select Interference of Sound.

EYES: Interference of Sound window opens.

08:20 At the bottom of the window, click on SQR1 and SQR2 check-boxes.
08:28 Click on START button. Beats pattern appears.
08:33 Now, click on Xmgrace button. A new window opens with a Grace pattern.
08:42 Click on FFT. A new window opens with Fourier Transform.
08:49 To know more about Fourier Transform , please visit this webpage.

https://en.wikipedia.org/wiki/Fourier_transform.

08:55 Let us perform an experiment to show a low frequency sound wave. This is the circuit diagram.
09:03 Click on EXPERIMENTS button and select Interference of Sound. EYES: Interference of Sound window opens.
09:13 At the bottom of the window, set the value of SQR1 to 100 and check the box.
09:21 Click on START button, a low amplitude wave is displayed.
09:29 Click on FFT to obtain a Grace plot of Fourier Transform.
09:34 Let's summarize.
09:36 In this tutorial, we have learnt to demonstrate:

how to generate a sound wave,

Frequency response of a sound source,

how to calculate velocity of sound waves,

Interference and Beat pattern of sound waves,

forced oscillations of sound source.

09:56 And, have shown:

Xmgrace plots,

Fourier Transforms and

Circuit diagrams for our experiments.

10:04 As an Assignment-

Capture a sound burst

Hint: A bell or a clap can be used as source of sound. This is the circuit diagram.

10:15 This video summarizes the Spoken Tutorial project. If you do not have good bandwidth, you can download and watch it.
10:24 We conduct workshops using Spoken Tutorials and give certificates. Please contact us.
10:32 The Spoken Tutorial Project is funded by NMEICT, MHRD, Government of India.
10:40 This tutorial is contributed by Kaushik Datta and Madhuri Ganapathi. This is Sakina Sidhwa.

Thank you for joining.

Contributors and Content Editors

Madhurig, Pratik kamble, Sandhya.np14