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I am using Goertzel algorithm to get the amplitude of a certain frequency. I am trying now to get the phase from it, and I don't know how.

Can some one explain, and show me how to get the phase of a certain-f from this code?

Also, I am using it to 16khz, with sample rate 44.1. What's the smallest length of samples that I can run it on?

double AlgorithmGoertzel( int16_t *sample,int sampleRate, double Freq, int len )
{
    double realW = 2.0 * cos(2.0 * M_PI * Freq / sampleRate);
    double imagW = 2.0 * sin(2.0 * M_PI * Freq / sampleRate);
    double d1 = 0;
    double d2 = 0;
    double y;
    for (int i = 0; i < len; i++) {
        y=(double)(signed short)sample[i] +realW * d1 - d2;
        d2 = d1;
        d1 = y;
    }
    double rR = 0.5 * realW *d1-d2;
    double rI = 0.5 * imagW *d1-d2;

    return (sqrt(pow(rR, 2)+pow(rI,2)))/len;
}
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I'm having problems understanding the last two results, rR and rI. Referring to the Wikipedia article, are they the real and imaginary part of the quantity y(N) in eq. 11? –  Coffee on Mars Nov 21 '12 at 9:26
    
"Phase" makes no sense unless you specify a phase relative to something, e.g. to some other signal or to some absolute point in time. It would help if you explained what you're really trying to achieve here? –  Paul R Nov 21 '12 at 9:28
    
possible duplicate of analyze audio in real time with narrow band-pass filter –  Paul R Nov 21 '12 at 9:30
1  
@PaulR , in that forum i guess there aren't people that knows dsp- such as you, so , find a life, and dont jump without a basic understanding of my question,and if you found that as a duplicate, why didnt you answer the original question ? –  Curnelious Nov 21 '12 at 13:19
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3 Answers

up vote 1 down vote accepted

I don't think the algorithm consists of multiplying the sequence by a constant, but by the complex signal exp(n*i*2pi*freq/samplerate); 0<=n<=length, and getting the average magnitude (or power of the signal).

As the complex output is R*exp(i theta), R gives the power at the given frequency and theta gives the phase. (theta == atan2 ( imag, real))

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Phase relative to what though ? It would be completely arbitrary and meaningless in this context. –  Paul R Nov 21 '12 at 9:29
1  
@PaulR phase does not have to be in relation to something, if you perform a bpsk , the phase is related to the previous phase . wish you could understand that . –  Curnelious Nov 21 '12 at 13:23
    
The first measurement gives you the reference phase... –  Aki Suihkonen Nov 21 '12 at 13:42
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The number of samples you need to feed a Goertzel filter will be inversely proportional to your desired or required filter bandwidth. A Goertzel provides a Sinc shaped bandpass filter, with the main lobe width proportional to 2*Fs/N.

If you use a complex Goertzel, the resulting phase will be relative to some point in the filter's data window. You may thus have to calculate an offset to get phase relative to some other reference point in time.

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thanks, so if i give it 50 samples i get a nice bw of 1700hz , the problem is, that 50 is a lot, and i can miss a lot, unless i am running on ALL of my samples and not every 50 samples- which than makes Goerzel less better than FFT, is that right ? –  Curnelious Nov 22 '12 at 7:51
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Do a rectangular to polar conversion. That will give you phase and magnitude.

magnitude = sqrt ((Vreal * Vreal) + (Vimag * Vimag))

phase = atan2 (Vimag, Vreal)

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