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I am currently using a metro app in VS2012. i have a c# code that records a user's voice and saves it into a wav file (16bit, 44.1kHz, mono). I have processed the pcm to only contain a double array data of values between -1 and 1 as shown below.

The next step is where I am stuck as I would like to do is to apply FFT on the double array data and convert it to a spectrogram. I would like to know if there is any FFT algorithm that takes in a double array preferably without the use of any library.

I would also like to know if of any way to convert this data(after FFT applied) to a spectrogram(to be used for comparing with another spectrogram later) using metro.

An example of a portion of my double array values which I would like to use it to apply FFT on it to get the frequency and show it visually.

This is the code which process my pcm data.

public static Double[] prepare(String wavePath)
    {
        Double[] data;
        byte[] wave;
        byte[] sR = new byte[4];
        System.IO.FileStream WaveFile = System.IO.File.OpenRead(wavePath);
        wave = new byte[WaveFile.Length];
        data = new Double[(wave.Length - 44) / 4];//shifting the headers out of the PCM data;
        WaveFile.Read(wave, 0, Convert.ToInt32(WaveFile.Length));//read the wave file into the wave variable
        /***********Converting and PCM accounting***************/
       for (int i = 0; i < data.Length; i ++)
        {
             data[i] = BitConverter.ToInt16(wave, i*2) / 32768.0;
        }
            //65536.0.0=2^n,       n=bits per sample;

        return data;
    }

Edited *This is my output*
-3.0517578125E-05
-3.0517578125E-05
-3.0517578125E-05
-3.0517578125E-05
-6.103515625E-05
-9.1552734375E-05
-6.103515625E-05
-6.103515625E-05
-6.103515625E-05
-6.103515625E-05
-9.1552734375E-05
-6.103515625E-05
-9.1552734375E-05
-6.103515625E-05
-9.1552734375E-05
-6.103515625E-05

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do you know why every second number is a 0? that looks odd... –  thalm Jul 2 '13 at 1:53
    
Im not sure. Its kinda odd for me too. Maybe if i put up the code i use to process my pcm data, u could point it out for me –  user2431088 Jul 2 '13 at 1:56
    
you increase i by two and write into data[i] so you only write into every second field. you need to increase i by one. e.g. i++ and use BitConverter.ToInt16(wave, i*2) to read out the bytes. And i also wonder why you don't account for the offset of the PCM header when you read the data? Maybe 'i' should start at 44? –  thalm Jul 2 '13 at 2:19
    
possible duplicate of How to generate the audio spectrum using fft in C++? –  Paul R Jul 2 '13 at 4:47
    
@thalm hi i have edited the code. u can ignore the part which i deleted away where i = 28 as that is to identify the Sample Rate. i manage to get values between -1 and 1 as shown in my output. However i have some values in the beginning which has alot of 0s in between. Is this a problem or is it suppose to act this way? –  user2431088 Jul 2 '13 at 10:32

1 Answer 1

up vote 2 down vote accepted

If you do a google search for c# FFT you will find may code examples. This one looked quite good, which i found here. The interesting thing is, that you can use your data with the 0 on every second place as input for the Table FFT which expects complex numbers if you want.

Always make sure you have data packages with power of 2 sample count.

    /// <summary>                                                                                            
    /// Compute the forward or inverse Fourier Transform of data, with data                                  
    /// containing complex valued data as alternating real and imaginary                                     
    /// parts. The length must be a power of 2. This method caches values                                    
    /// and should be slightly faster on than the FFT method for repeated uses.                              
    /// It is also slightly more accurate. Data is transformed in place.                                     
    /// </summary>                                                                                           
    /// <param name="data">The complex data stored as alternating real                                       
    /// and imaginary parts</param>                                                                          
    /// <param name="forward">true for a forward transform, false for                                        
    /// inverse transform</param>                                                                            
    public void TableFFT(double[] data, bool forward)                                                        
    {                                                                                                        
        var n = data.Length;                                                                                 
        // checks n is a power of 2 in 2's complement format                                                 
        if ((n & (n - 1)) != 0)                                                                              
            throw new ArgumentException(                                                                     
                "data length " + n + " in FFT is not a power of 2"                                           
                );                                                                                           
        n /= 2;    // n is the number of samples                                                             

        Reverse(data, n); // bit index data reversal                                                         

        // make table if needed                                                                              
        if ((cosTable == null) || (cosTable.Length != n))                                                    
            Initialize(n);                                                                                   

        // do transform: so single point transforms, then doubles, etc.                                      
        double sign = forward ? B : -B;                                                                      
        var mmax = 1;                                                                                        
        var tptr = 0;                                                                                        
        while (n > mmax)                                                                                     
        {                                                                                                    
            var istep = 2 * mmax;                                                                            
            for (var m = 0; m < istep; m += 2)                                                               
            {                                                                                                
                var wr = cosTable[tptr];                                                                     
                var wi = sign * sinTable[tptr++];                                                            
                for (var k = m; k < 2 * n; k += 2 * istep)                                                   
                {                                                                                            
                    var j = k + istep;                                                                       
                    var tempr = wr * data[j] - wi * data[j + 1];                                             
                    var tempi = wi * data[j] + wr * data[j + 1];                                             
                    data[j] = data[k] - tempr;                                                               
                    data[j + 1] = data[k + 1] - tempi;                                                       
                    data[k] = data[k] + tempr;                                                               
                    data[k + 1] = data[k + 1] + tempi;                                                       
                }                                                                                            
            }                                                                                                
            mmax = istep;                                                                                    
        }                                                                                                    


        // perform data scaling as needed                                                                    
        Scale(data, n, forward);                                                                             
    }  

    /// <summary>                                                                                            
    /// Compute the forward or inverse Fourier Transform of data, with                                       
    /// data containing real valued data only. The output is complex                                         
    /// valued after the first two entries, stored in alternating real                                       
    /// and imaginary parts. The first two returned entries are the real                                     
    /// parts of the first and last value from the conjugate symmetric                                       
    /// output, which are necessarily real. The length must be a power                                       
    /// of 2.                                                                                                
    /// </summary>                                                                                           
    /// <param name="data">The complex data stored as alternating real                                       
    /// and imaginary parts</param>                                                                          
    /// <param name="forward">true for a forward transform, false for                                        
    /// inverse transform</param>                                                                            
    public void RealFFT(double[] data, bool forward)                                                         
    {                                                                                                        

        var n = data.Length; // # of real inputs, 1/2 the complex length                                     
        // checks n is a power of 2 in 2's complement format                                                 
        if ((n & (n - 1)) != 0)                                                                              
            throw new ArgumentException(                                                                     
                "data length " + n + " in FFT is not a power of 2"                                           
                );                                                                                           

        var sign = -1.0; // assume inverse FFT, this controls how algebra below works                        
        if (forward)                                                                                         
        { // do packed FFT. This can be changed to FFT to save memory                                        
            TableFFT(data, true);                                                                            
            sign = 1.0;                                                                                      
            // scaling - divide by scaling for N/2, then mult by scaling for N                               
            if (A != 1)                                                                                      
            {                                                                                                
                var scale = Math.Pow(2.0, (A - 1) / 2.0);                                                    
                for (var i = 0; i < data.Length; ++i)                                                        
                    data[i] *= scale;                                                                        
            }                                                                                                
        }                                                                                                    

        var theta = B * sign * 2 * Math.PI / n;                                                              
        var wpr = Math.Cos(theta);                                                                           
        var wpi = Math.Sin(theta);                                                                           
        var wjr = wpr;                                                                                       
        var wji = wpi;                                                                                       

        for (var j = 1; j <= n/4; ++j)                                                                       
        {                                                                                                    
            var k = n / 2 - j;                                                                               
            var tkr = data[2 * k];    // real and imaginary parts of t_k  = t_(n/2 - j)                      
            var tki = data[2 * k + 1];                                                                       
            var tjr = data[2 * j];    // real and imaginary parts of t_j                                     
            var tji = data[2 * j + 1];                                                                       

            var a = (tjr - tkr) * wji;                                                                       
            var b = (tji + tki) * wjr;                                                                       
            var c = (tjr - tkr) * wjr;                                                                       
            var d = (tji + tki) * wji;                                                                       
            var e = (tjr + tkr);                                                                             
            var f = (tji - tki);                                                                             

            // compute entry y[j]                                                                            
            data[2 * j] = 0.5 * (e + sign * (a + b));                                                        
            data[2 * j + 1] = 0.5 * (f + sign * (d - c));                                                    

            // compute entry y[k]                                                                            
            data[2 * k] = 0.5 * (e - sign * (b + a));                                                        
            data[2 * k + 1] = 0.5 * (sign * (d - c) - f);                                                    

            var temp = wjr;                                                                                  
            // todo - allow more accurate version here? make option?                                         
            wjr = wjr * wpr - wji * wpi;                                                                     
            wji = temp * wpi + wji * wpr;                                                                    
        }                                                                                                    

        if (forward)                                                                                         
        {                                                                                                    
            // compute final y0 and y_{N/2}, store in data[0], data[1]                                       
            var temp = data[0];                                                                              
            data[0] += data[1];                                                                              
            data[1] = temp - data[1];                                                                        
        }                                                                                                    
        else                                                                                                 
        {                                                                                                    
            var temp = data[0]; // unpack the y0 and y_{N/2}, then invert FFT                                
            data[0] = 0.5 * (temp + data[1]);                                                                
            data[1] = 0.5 * (temp - data[1]);                                                                
            // do packed inverse (table based) FFT. This can be changed to regular inverse FFT to save memory
            TableFFT(data, false);                                                                           
            // scaling - divide by scaling for N, then mult by scaling for N/2                               
            //if (A != -1) // todo - off by factor of 2? this works, but something seems weird               
            {                                                                                                
                var scale = Math.Pow(2.0, -(A + 1) / 2.0)*2;                                                 
                for (var i = 0; i < data.Length; ++i)                                                        
                    data[i] *= scale;                                                                        
            }                                                                                                
        }                                                                                                    
    }                                                                                                        

    /// <summary>                                                                                            
    /// Determine how scaling works on the forward and inverse transforms.                                   
    /// For size N=2^n transforms, the forward transform gets divided by                                     
    /// N^((1-a)/2) and the inverse gets divided by N^((1+a)/2). Common                                      
    /// values for (A,B) are                                                                                 
    ///     ( 0, 1)  - default                                                                               
    ///     (-1, 1)  - data processing                                                                       
    ///     ( 1,-1)  - signal processing                                                                     
    /// Usual values for A are 1, 0, or -1                                                                   
    /// </summary>                                                                                           
    public int A { get; set; }                                                                               

    /// <summary>                                                                                            
    /// Determine how phase works on the forward and inverse transforms.                                     
    /// For size N=2^n transforms, the forward transform uses an                                             
    /// exp(B*2*pi/N) term and the inverse uses an exp(-B*2*pi/N) term.                                      
    /// Common values for (A,B) are                                                                          
    ///     ( 0, 1)  - default                                                                               
    ///     (-1, 1)  - data processing                                                                       
    ///     ( 1,-1)  - signal processing                                                                     
    /// Abs(B) should be relatively prime to N.                                                              
    /// Setting B=-1 effectively corresponds to conjugating both input and                                   
    /// output data.                                                                                         
    /// Usual values for B are 1 or -1.                                                                      
    /// </summary>                                                                                           
    public int B { get; set; } 

    /// <summary>                                                                                            
    /// Scale data using n samples for forward and inverse transforms as needed                              
    /// </summary>                                                                                           
    /// <param name="data"></param>                                                                          
    /// <param name="n"></param>                                                                             
    /// <param name="forward"></param>                                                                       
    void Scale(double[] data, int n, bool forward)                                                           
    {                                                                                                        
        // forward scaling if needed                                                                         
        if ((forward) && (A != 1))                                                                           
        {                                                                                                    
            var scale = Math.Pow(n, (A - 1) / 2.0);                                                          
            for (var i = 0; i < data.Length; ++i)                                                            
                data[i] *= scale;                                                                            
        }                                                                                                    

        // inverse scaling if needed                                                                         
        if ((!forward) && (A != -1))                                                                         
        {                                                                                                    
            var scale = Math.Pow(n, -(A + 1) / 2.0);                                                         
            for (var i = 0; i < data.Length; ++i)                                                            
                data[i] *= scale;                                                                            
        }                                                                                                    
    }
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