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This is all done in MATLAB 2010

My objective is to show the results of: undersampling, nyquist rate/ oversampling

First i need to downsample the .wav file to get an incomplete/ or impartial data stream that i can then reconstuct.

Heres the flow chart of what im going to be doing So the flow is analog signal -> sampling analog filter -> ADC -> resample down -> resample up -> DAC -> reconstruction analog filter

what needs to be achieved:

F= Frequency

F(Hz=1/s) E.x. 100Hz = 1000 (Cyc/sec) F(s)= 1/(2f)

Example problem: 1000 hz = Highest frequency 1/2(1000hz) = 1/2000 = 5x10(-3) sec/cyc or a sampling rate of 5ms

This is my first signal processing project using matlab.

what i have so far.

% Fs = frequency sampled (44100hz or the sampling frequency of a cd)

[test,fs]=wavread('test.wav'); % loads the .wav file

% Plot of the .wav signal time vs. strength

xlabel('time (sec)');
ylabel('relative signal strength')

**%this is were i would need to sample it at the different frequecys (both above and below and at) nyquist frequency.*I think.***

soundsc(left,fs) % shows the resaultant audio file , which is the same as original ( only at or above nyquist frequency however) 

Can anyone tell me how to make it better, and how to do the sampling at verious frequencies?

heres the .wav file


%Play decimated file ( soundsc(y,fs) ) 
%Play Original file ( soundsc(play,fs ) )
%Play reconstucted File ( soundsc(final,fs) )

[piano,fs]=wavread('piano.wav'); % loads piano
play=piano(:,1); % Renames the file as "play"

t = linspace(0,time,length(play));          % Time vector
x = play;
y = decimate(x,25);

stem(x(1:30)), axis([0 30 -2 2])   % Original signal
title('Original Signal')
stem(y(1:30))                        % Decimated signal
title('Decimated Signal')

%changes the sampling rate

fs1 = fs/2;
fs2 = fs/3;
fs3 = fs/4;
fs4 = fs*2;
fs5 = fs*3;
fs6 = fs*4;



%Downsampled version of piano is now upsampled to the original
[PianoDecimation,fs]=wavread('PianoDecimation.wav'); % loads piano
play2=PianoDecimation(:,1); % Renames the file as "play

UpSampleRatio = 2;  % 2*fs = nyquist rate sampling
play2Up=zeros(length(PianoDecimation)*UpSampleRatio, 1);
play2Up(1:UpSampleRatio:end) = play2; % fill in every N'th sample

%low pass filter

ResampFilt = firpm(44, [0 0.39625 0.60938 1], [1 1 0 0]);

fsUp = (fs*UpSampleRatio)*1;

%data vs time plot
title('Upsampled graph of piano')
ylabel('relative signal strength')

[PianoUpsampled,fs]=wavread('PianoUpsampled.wav'); % loads piano
final=PianoUpsampled(:,1); % Renames the file as "play"

[piano,fs]=wavread('piano.wav'); % loads piano
x=piano(:,1); % Renames the file as "play"
m = resample(x,3,2);



share|improve this question
what do you mean, from my previous questions ive asked about nyquist sampling using a msp430 micro controller, this has nothing to do with that. – Andrew Dec 28 '10 at 2:56
It means you click the green checkmark on an answer for one of your previous questions, as done in this question. It awards the author extra points and allows future users & searchers to see which answer was most helpful. – tyblu Dec 28 '10 at 5:25
Most helpful for my question about the msp430 board yea. . . – Andrew Dec 28 '10 at 14:16

The easiest thing to do is change sample rates by an integer factor. Downsampling consists of running the data through a low-pass filter followed by discarding samples, while upsampling consists of inserting samples then running the data through a low pass filter (also known as a reconstruction filter or interpolating filter). Aliasing occurs when the filtering steps are skipped or poorly done. So, to show the effect of aliasing, I suggest you simply discard or insert samples as required, then create a new WAV file at the new sample rate. To discard samples, you can do:

DownSampleRatio = 2;
%# Normally apply a low pass filter here
leftDown = left(1:DownSampleRatio:end); %# extract every N'th sample
fsDown = fs/DownSampleRatio;
wavwrite(leftDown, fsDown, filename);

To create samples you can do:

UpSampleRatio = 2;
leftUp = zeros(length(left)*UpSampleRatio, 1);
leftUp(1:UpSampleRatio:end) = left; %# fill in every N'th sample
%# Normally apply a low pass filter here
fsUp = fs*UpSampleRatio;
wavwrite(leftUp, fsUp, filename);

You can just play back the written WAV files to hear the effects.

As an aside, you asked for improvements to your code - I prefer to initialize the t vector as t = (0:(length(left)-1))/fs;.

share|improve this answer
Shouldnt they sound the same once this is done, when i tried it , it doesn't sound the same at all. – Andrew Dec 28 '10 at 15:11
Both processes introduce aliasing, so no, they shouldn't sound the same. You would have to (a) ensure that the original signal didn't have energy above fsDown/2 and (b) include the low-pass filtering steps I mentioned above for them to sound the same. – mtrw Dec 28 '10 at 15:18
yea i added a low pass filter, ill edit the code uptop so you can see it. – Andrew Dec 28 '10 at 15:30
First, that low pass filter is weak. You need to make sure it attenuates everything above fsDown/2. Second, in upsampling, you need to apply it to the upsampled data. – mtrw Dec 28 '10 at 15:50
The low pass filter? its applied to both, but what would a better low lass filter be instead of the current one? and instead of downsampling decimation would be better as Clifford said. i need to find a way to implement it to a audio file rather then a sine wave. – Andrew Dec 28 '10 at 15:59

The DSP technique you need is called decimation.

share|improve this answer
yea, i was reading online and i saw this. . Im trying to figure out how to implement it with a audio file instead of a sine wave. So, y=decimate(x,r) were x = audio file and r is the factor at which its decimated? – Andrew Dec 28 '10 at 16:00
@Andrew: Their example data is not a sine wave, it is the sum of two sine waves, and audio signal is (like any other signal) the sum of a number of sine waves of differing amplitude, frequency and phase. There is no difference between using a variable representing an audio stream and one mathematically generated. You simply use your audio sample variable in place of their x variable. Matlab has a function for reading a WAV file into such a variable. – Clifford Dec 29 '10 at 10:32
yea i know, look at my new code. – Andrew Dec 29 '10 at 13:06

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