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im trying to estimate the fundamental frequency from a .wav file which contains a recording of the speech of 1 word.

What i've tried to do is to read the file with audioInputStream. The format is PCM_SIGNED 44100.0 Hz, 16 bit, stereo, 4 bytes/frame, little-endian.

Therefore i have made a new buffer to contain just one channel. This code achieves that:

double [] audioRight = new double[audioBytes.length/2]; 
for(int i = 0, k = 0; i <= audioBytes.length-1; i+=4, k+=2){
    audioRight[k]=audioBytes[i];
    audioRight[k+1]=audioBytes[i+1];
}

Then the data was moved to a fftBuffer, which is twice the size, and then an DFT is applied. The library used is JTransform. the function used is called realForwardFull.

DoubleFFT_1D fftDo= new DoubleFFT_1D(audioLeft.length);
double[] fftBuffer = new double [audioLeft.length*2];

for (int i = 0; i < audioLeft.length; i++){
     fftBuffer[i] = audioLeft[i];
}
fftDo.realForwardFull(fftBuffer);

This gives a list of complex numbers which I use to calculate the magnitude/amplitude of each complex number in order to make a power spectrum.

The formula used to get the amplitude Amplitude=sqrt(IM*IM+RE*RE).

This provides an array of amplitudes which I apply the harmonic summation method to. Harmonic summation is where the index + 3 harmonics that gives the highest sum is the index that represents the fundamental frequency.

double top_sum = 0;
double first_index = 0;
double sum = 0;
double f_0 = 0;
double FR = audioInputStream.getFormat().getSampleRate()/2/ampBuffer.length;

for (int i = 50; i <= ampBuffer.length/4-1; i++){
sum = ampBuffer[i]+ampBuffer[i*2]+ampBuffer[i*3]+ampBuffer[i*4];
     if (top_sum < sum){
 top_sum=sum;
 first_index = i;

This index however needs to be mapped back to the correct frequency domnain. To my understanding that should be done by saying (index / fttBuffer.length)*sampleRate.

This provides an estimate of the fundamental frequency.

The result however is not "correct". I have several different .wav files to test on, and with most of them the result is way outside the expected range. For the same female voices, three different words gives the results 40, 13 and 360. All three results are expected to be in the range 250 to 350, approximately.

Some of the issues I think is causing this is the amplitude buffer values. When plotted the graph doesnt show any clear peaks that represents the harmoncis.

Here's an image of the graph:

Amplitudes

I know this was a lot of information, but I believe more information makes it easier to understand what has been done.

RECAP: What I am unsure of is the amplitude data. Does the values make sense? Are they plotted correctly? Do i need to do something with the data before i search it for the harmoncis and find the fundamental frequency?

I have considered to apply some kind of windowing, because I have a suspicion that leakage might be why the peaks that the plot does have isnt harmonics to each other.

Any help or suggestions would be appreciated. In advance, thank you for your help!

EDIT: As an attempt to what was suggested:

 ByteBuffer buf = ByteBuffer.wrap(audioBytes);
         buf.order(ByteOrder.LITTLE_ENDIAN);
         double[] audio = new double[audioBytes.length/2];  


         for(int i = 0; i < audioBytes.length/2; i++) {
             short s = buf.getShort();
             double mono = (double) s;
             double mono_norm = mono / 32768.0;

             audio[i]=mono_norm;


         }

Now one channel of the pcm data should be saved in the array audio[].

share|improve this question
    
16 bits is 2 bytes. Where are you converting little-endian 2 bytes into 1 double value? – hotpaw2 Jul 21 '13 at 0:25
    
Thanks for your answer. I have not done that. What is the point of doing it? and do you have a suggestion as to how it can be done in java? – Mark Kronborg Jul 22 '13 at 12:42
    
@hotpaw2 I have edited the original post with an attempt of applying what you suggested. Is this what you meant? it doesnt seem to solve my problem, if i did it correct that is. – Mark Kronborg Jul 22 '13 at 13:40
    
Turns out using the ByteBuffer.wrap fixed my problem, so thank you for pointing me in that direction. After using the byteBuffer and focusing on the first 1000 values in my buffer i can now estimate the fundamental frequencies of .wav files of speech. The results fit in the expected intervals for fundamental frequency for each gender. If anyone is reading this post looking for answers regarding fundamental frequency estimation with Harmonics Spectrum Summation, then ask for it and i will dump the entire code i used for it. I know how hard it is to find good information on the subject ( : – Mark Kronborg Jul 23 '13 at 18:43
    
Stereo, 16 bits -> 4 bytes. One sample Little Endiannes: WavSample = (int)(((Bytes[1]) << 8)|((Bytes[0] & 0xFF) << 0)); One Sample Big endianness WavSample = (int)(((Bytes[0]) << 8)|((Bytes[1] & 0xFF) << 0)); Check if you are reading correctly the samples... Each sample have 4 bytes, 2 per sample (short) and consecutively have stereo (2 channels) then you need to jumb each 4 bytes, and read first 2 byte one channel (left) last 2 byte other channel (right). – chepe lucho Oct 1 '13 at 23:33

Some general hints:

You say you try to estimate the fundamental frquency of one spoken word. A "word" consists of several consonants and vowels (or better phonemes). Each of the "vowels" will have a different fundamental frequency and in most cases the frequency will even change within one vowel (which generates the "melody" of our sentences). Thius means you should estimate the fundamental frequency / pitch of a very short interval of the speech and make sure you are looking at a vowel (consonants are some form of noise and have cyclic components).

So the first sterp should be to generate a spectogram of your word.

Then you may calculate Short-Term-FFTs of the interesting parts and proceed with harmonic summation.

You will get better results with a short term autocorrelation function however.

Other things to research: Pitch-Detection, Cepstrum

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