# FFT algorithm getting wrong sound frequency value

I have performed a FFT algorithm(it is partially MIT) on a 440Hz sample link to the sound sample ttp://www.speedyshare.com/R6d9g/440.wav. But I get wrong sound frequency -> 510Hz.

1.Is the byteArray containing .wav is correctly converted into 2 double arrays(Re Im part). The imaginary array contains only 0.

2.I assume that the highest sound frequency is the maximum of xRe array: please look at the very end of the run() function? Maybe that is my mistake it is average or something like that?

What is problem then?

UPDATED: The biggest sum Re+Im is at index = 0 so i get frequency = 0;

Whole project, contains .wav -> just open and run: http://speedy.sh/W5kAm/FFT3.zip

``````using System;
using System.Net;
using System.IO;

namespace FFT {

public class FFT2 {
// Element for linked list in which we store the
// input/output data. We use a linked list because
// for sequential access it's faster than array index.
class FFTElement {
public double re = 0.0;     // Real component
public double im = 0.0;     // Imaginary component
public FFTElement next;     // Next element in linked list
public uint revTgt;         // Target position post bit-reversal
}
private static int sampleRate;
private uint m_logN = 0;        // log2 of FFT size
private uint m_N = 0;           // FFT size
private FFTElement[] m_X;       // Vector of linked list elements

/**
*
*/
public FFT2() {
}

/**
* Initialize class to perform FFT of specified size.
*
* @param   logN    Log2 of FFT length. e.g. for 512 pt FFT, logN = 9.
*/
public void init(uint logN) {
m_logN = logN;
m_N = (uint)(1 << (int)m_logN);

// Allocate elements for linked list of complex numbers.
m_X = new FFTElement[m_N];
for (uint k = 0; k < m_N; k++)
m_X[k] = new FFTElement();

// Set up "next" pointers.
for (uint k = 0; k < m_N - 1; k++)
m_X[k].next = m_X[k + 1];

// Specify target for bit reversal re-ordering.
for (uint k = 0; k < m_N; k++)
m_X[k].revTgt = BitReverse(k, logN);
}

/**
* Performs in-place complex FFT.
*
* @param   xRe     Real part of input/output
* @param   xIm     Imaginary part of input/output
* @param   inverse If true, do an inverse FFT
*/
public void run(double[] xRe, double[] xIm, bool inverse = false) {
uint numFlies = m_N >> 1;   // Number of butterflies per sub-FFT
uint span = m_N >> 1;       // Width of the butterfly
uint spacing = m_N;         // Distance between start of sub-FFTs
uint wIndexStep = 1;        // Increment for twiddle table index

// Copy data into linked complex number objects
// If it's an IFFT, we divide by N while we're at it
FFTElement x = m_X[0];
uint k = 0;
double scale = inverse ? 1.0 / m_N : 1.0;
while (x != null) {
x.re = scale * xRe[k];
x.im = scale * xIm[k];
x = x.next;
k++;
}

// For each stage of the FFT
for (uint stage = 0; stage < m_logN; stage++) {
// Compute a multiplier factor for the "twiddle factors".
// The twiddle factors are complex unit vectors spaced at
// regular angular intervals. The angle by which the twiddle
// factor advances depends on the FFT stage. In many FFT
// implementations the twiddle factors are cached, but because
// array lookup is relatively slow in C#, it's just
// as fast to compute them on the fly.
double wAngleInc = wIndexStep * 2.0 * Math.PI / m_N;
if (inverse == false)
wAngleInc *= -1;
double wMulRe = Math.Cos(wAngleInc);
double wMulIm = Math.Sin(wAngleInc);

for (uint start = 0; start < m_N; start += spacing) {
FFTElement xTop = m_X[start];
FFTElement xBot = m_X[start + span];

double wRe = 1.0;
double wIm = 0.0;

// For each butterfly in this stage
for (uint flyCount = 0; flyCount < numFlies; ++flyCount) {
// Get the top & bottom values
double xTopRe = xTop.re;
double xTopIm = xTop.im;
double xBotRe = xBot.re;
double xBotIm = xBot.im;

// Top branch of butterfly has addition
xTop.re = xTopRe + xBotRe;
xTop.im = xTopIm + xBotIm;

// Bottom branch of butterly has subtraction,
// followed by multiplication by twiddle factor
xBotRe = xTopRe - xBotRe;
xBotIm = xTopIm - xBotIm;
xBot.re = xBotRe * wRe - xBotIm * wIm;
xBot.im = xBotRe * wIm + xBotIm * wRe;

// Advance butterfly to next top & bottom positions
xTop = xTop.next;
xBot = xBot.next;

// Update the twiddle factor, via complex multiply
// by unit vector with the appropriate angle
// (wRe + j wIm) = (wRe + j wIm) x (wMulRe + j wMulIm)
double tRe = wRe;
wRe = wRe * wMulRe - wIm * wMulIm;
wIm = tRe * wMulIm + wIm * wMulRe;
}
}

numFlies >>= 1;     // Divide by 2 by right shift
span >>= 1;
spacing >>= 1;
wIndexStep <<= 1;   // Multiply by 2 by left shift
}

// The algorithm leaves the result in a scrambled order.
// Unscramble while copying values from the complex
// linked list elements back to the input/output vectors.
x = m_X[0];
while (x != null) {
uint target = x.revTgt;
xRe[target] = x.re;
xIm[target] = x.im;
x = x.next;
}

//looking for max  IS THIS IS FREQUENCY
double max = 0, index = 0;
for (int i = 0; i < xRe.Length; i++) {
if (xRe[i] + xIm[i] > max) {
max = xRe[i]*xRe[i] + xIm[i]*xIm[i];
index = i;
}
}
max = Math.Sqrt(max);
/*   if the peak is at bin index i then the corresponding
frequency will be i * Fs / N whe Fs is the sample rate in Hz and N is the FFT size.*/

//DONT KNOW WHY THE BIGGEST VALUE IS IN THE BEGINNING
Console.WriteLine("max "+ max+" index " + index + " m_logN" + m_logN + " " + xRe[0]);
max = index * sampleRate / m_logN;
Console.WriteLine("max " + max);
}

/**
* Do bit reversal of specified number of places of an int
* For example, 1101 bit-reversed is 1011
*
* @param   x       Number to be bit-reverse.
* @param   numBits Number of bits in the number.
*/
private uint BitReverse(
uint x,
uint numBits) {
uint y = 0;
for (uint i = 0; i < numBits; i++) {
y <<= 1;
y |= x & 0x0001;
x >>= 1;
}
return y;
}
public static void Main(String[] args) {

if (fmtSize == 18) {
}

// Store the audio data of the wave file to a byte array.

/*    for (int i = 0; i < byteArray.Length; i++) {
Console.Write(byteArray[i] + " ");
}*/

byte[] data = byteArray;
double[] arrRe = new double[data.Length];
for (int i = 0; i < arrRe.Length; i++) {
arrRe[i] = data[i] / 32768.0;
}
double[] arrI = new double[data.Length];
for (int i = 0; i < arrRe.Length; i++) {
arrI[i] = 0;
}

/**
* Initialize class to perform FFT of specified size.
*
* @param logN    Log2 of FFT length. e.g. for 512 pt FFT, logN = 9.
*/
Console.WriteLine();
FFT2 fft2 = new FFT2();
uint logN = (uint)Math.Log(data.Length, 2);
fft2.init(logN);

fft2.run(arrRe, arrI);
// After this you have to split that byte array for each channel (Left,Right)
// Wav supports many channels, so you have to read channel from header
}
}
}
``````
-

There are a few things that you need to address:

• you're not applying a window function prior to the FFT - this will result in spectral leakage in the general case and you may get misleading results, particularly when looking for peaks, as there will be "smearing" of the spectrum.

• when looking for peaks you should be looking at the magnitude of FFT output bins, not the individual real and imaginary parts - `magnitude = sqrt(re^2 +im^2)` (although you don't need to worry about the `sqrt` if you're just looking for peaks).

• having identified a peak you need to convert the bin index into a frequency - if the peak is at bin index i then the corresponding frequency will be `i * Fs / N` where `Fs` is the sample rate in Hz and `N` is the FFT size.

• for a real-to-complex FFT you can ignore the second N / 2 output bins as they are just the complex conjugate mirror image of the first N / 2 bins