(New page: '''Composed by Chen Chen''' You may still remember the Vuvuzelas during the South Africa, which is horribly annoying. Unfortunately nearly 98% of the Vuvuzelas are made in China with very ...)
 
 
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'''Composed by Chen Chen'''
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[[Category:bonus point project]]
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=Vuvuzelas=
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'''Composed by Chen Chen''' for the course [[ECE438]]
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----
 
You may still remember the Vuvuzelas during the South Africa, which is horribly annoying.
 
You may still remember the Vuvuzelas during the South Africa, which is horribly annoying.
 +
 
Unfortunately nearly 98% of the Vuvuzelas are made in China with very low prices and resulting in huge disturbance to the game, I feel strong obligated to design a filter to remove the noise.
 
Unfortunately nearly 98% of the Vuvuzelas are made in China with very low prices and resulting in huge disturbance to the game, I feel strong obligated to design a filter to remove the noise.
  
Analysis:
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==Analysis:==
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There are 3 major sound components of a soccer game on TV:  
 
There are 3 major sound components of a soccer game on TV:  
1. Game commentator's voice
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2. Game background sounds: audience cheering, referee whistle, coach and players yelling ( which give you sound-surround ambiance)
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# Game commentator's voice
3. Vuvuzelas noise
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Frequency analysis:
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# Game background sounds: audience cheering, referee whistle, coach and players yelling ( which give you sound-surround ambiance)
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# Vuvuzelas noise
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==Frequency analysis:==
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The frequency analysis shows that human voice range is approximately 80Hz-700Hz.
 
The frequency analysis shows that human voice range is approximately 80Hz-700Hz.
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The frequency of Vuvuzelas needs more effort to analysis.
 
The frequency of Vuvuzelas needs more effort to analysis.
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There are multiple plots of frequency analysis of Vuvuzelas:
 
There are multiple plots of frequency analysis of Vuvuzelas:
[[Image:Vuvuzelas.jpg]]
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This is the separated waveform plot of Vuvuzelas, showing that it is periodic. Which is very convenient to implement DSP methods using  Fourier transform.
 
This is the separated waveform plot of Vuvuzelas, showing that it is periodic. Which is very convenient to implement DSP methods using  Fourier transform.
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Further exploration of the waveform, the dB plot is as following:
 
Further exploration of the waveform, the dB plot is as following:
[[Image:Vuvu2.jpg]]
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This is dB plot of Vuvuzelas sound.  
 
This is dB plot of Vuvuzelas sound.  
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In the plots, the frequency range is from 50Hz to 7000Hz, but there are several dominant formants at 192Hz 233Hz 466Hz 932Hz and 1864Hz
 
In the plots, the frequency range is from 50Hz to 7000Hz, but there are several dominant formants at 192Hz 233Hz 466Hz 932Hz and 1864Hz
  
Design:
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==Design:==
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In order to remove the noise from Vuvuzelas, we need to implement a couple of high frequency band-stop filters.
 
In order to remove the noise from Vuvuzelas, we need to implement a couple of high frequency band-stop filters.
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Each filter is used to remove corresponding frequency component.
 
Each filter is used to remove corresponding frequency component.
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Notch filter is an ideal band-stop filter with a narrow stopband (high Q factor) which are used in live sound reproduction.
 
Notch filter is an ideal band-stop filter with a narrow stopband (high Q factor) which are used in live sound reproduction.
[[Image:Bandstop.jpg]]
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This is the frequency response of a notch filter
 
This is the frequency response of a notch filter
  
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The audio signal will go through the filters connected in series and the output will be a much better audio signal with Vuvuzelas noise greatly reduced.  
 
The audio signal will go through the filters connected in series and the output will be a much better audio signal with Vuvuzelas noise greatly reduced.  
[[Image:Notch.jpg]]
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This is the frequency response of audio signal after notch filter with stop band around 192Hz
 
This is the frequency response of audio signal after notch filter with stop band around 192Hz
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From previous plot, we can see, that the 192Hz component is greatly reduced.
 
From previous plot, we can see, that the 192Hz component is greatly reduced.
 +
 
Also, additional filter which enhance the frequency components for 80-700Hz except 192Hz 233Hz and 466Hz,will give better filtered game sound.
 
Also, additional filter which enhance the frequency components for 80-700Hz except 192Hz 233Hz and 466Hz,will give better filtered game sound.
'''Composed by Chen Chen.'''
 
  
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'''Composed by Chen Chen.'''
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----
 
Reference
 
Reference
http://goodog.uueasy.com/read-htm-tid-3343.html
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*http://goodog.uueasy.com/read-htm-tid-3343.html
http://www.yangtse.com/news/ty/201006/t20100618_743429.htm
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*http://www.yangtse.com/news/ty/201006/t20100618_743429.htm
http://www.answers.com/topic/band-stop-filter
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*http://www.answers.com/topic/band-stop-filter
http://en.wikipedia.org/wiki/Band-stop_filter
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*http://en.wikipedia.org/wiki/Band-stop_filter
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----
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==Questions/comments==
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*Write a comment here.
 +
**Answer here.
 +
----
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[[2010_Fall_ECE_438_Boutin|Back to ECE438 Fall 2010]]
 +
 
 +
[[ECE438|Back to ECE438]]

Latest revision as of 07:53, 11 November 2013

Vuvuzelas

Composed by Chen Chen for the course ECE438


You may still remember the Vuvuzelas during the South Africa, which is horribly annoying.

Unfortunately nearly 98% of the Vuvuzelas are made in China with very low prices and resulting in huge disturbance to the game, I feel strong obligated to design a filter to remove the noise.

Analysis:

There are 3 major sound components of a soccer game on TV:

  1. Game commentator's voice
  1. Game background sounds: audience cheering, referee whistle, coach and players yelling ( which give you sound-surround ambiance)
  1. Vuvuzelas noise

Frequency analysis:

The frequency analysis shows that human voice range is approximately 80Hz-700Hz.

The frequency of Vuvuzelas needs more effort to analysis.

There are multiple plots of frequency analysis of Vuvuzelas:

This is the separated waveform plot of Vuvuzelas, showing that it is periodic. Which is very convenient to implement DSP methods using Fourier transform.

Further exploration of the waveform, the dB plot is as following:

This is dB plot of Vuvuzelas sound.

In the plots, the frequency range is from 50Hz to 7000Hz, but there are several dominant formants at 192Hz 233Hz 466Hz 932Hz and 1864Hz

Design:

In order to remove the noise from Vuvuzelas, we need to implement a couple of high frequency band-stop filters.

Each filter is used to remove corresponding frequency component.

Notch filter is an ideal band-stop filter with a narrow stopband (high Q factor) which are used in live sound reproduction.

This is the frequency response of a notch filter

By varying the Q parameter of notch filter, it is possible to design notch filter with narrow stop bands around192Hz 233Hz 466Hz 932Hz and 1864Hz.

The audio signal will go through the filters connected in series and the output will be a much better audio signal with Vuvuzelas noise greatly reduced.

This is the frequency response of audio signal after notch filter with stop band around 192Hz

From previous plot, we can see, that the 192Hz component is greatly reduced.

Also, additional filter which enhance the frequency components for 80-700Hz except 192Hz 233Hz and 466Hz,will give better filtered game sound.

Composed by Chen Chen.


Reference


Questions/comments

  • Write a comment here.
    • Answer here.

Back to ECE438 Fall 2010

Back to ECE438

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Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

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