I am trying to filter some data based on the the following code using Arduino FFT library for FFT (fast Fourier transform)

guest openmusiclabs.com 7.7.14
example sketch for testing the fft library.
it takes in data on ADC0 (Analog0) and processes them
with the fft. the data is sent out over the serial
port at 115.2kb.

#define LOG_OUT 1 // use the log output function
#define FFT_N 256 // set to 256 point fft

#include <FFT.h> // include the library

void setup() {
  Serial.begin(115200); // use the serial port
  TIMSK0 = 0; // turn off timer0 for lower jitter
  ADCSRA = 0xe5; // set the adc to free running mode
  ADMUX = 0x40; // use adc0
  DIDR0 = 0x01; // turn off the digital input for adc0

void loop() {
  while(1) { // reduces jitter
    cli();  // UDRE interrupt slows this way down on arduino1.0
    for (int i = 0 ; i < 512 ; i += 2) { // save 256 samples
      while(!(ADCSRA & 0x10)); // wait for adc to be ready
      ADCSRA = 0xf5; // restart adc
      byte m = ADCL; // fetch adc data
      byte j = ADCH;
      int k = (j << 8) | m; // form into an int

      k -= 0x0200; // form into a signed int
      k <<= 6; // form into a 16b signed int
      fft_input[i] = k; // put real data into even bins
     // Serial.print(millis());
     // Serial.print("input ");
     // Serial.print(i);
    //  Serial.print(" = ");
      fft_input[i+1] = 0; // set odd bins to 0
    fft_window(); // window the data for better frequency response
    fft_reorder(); // reorder the data before doing the fft
    fft_run(); // process the data in the fft
    fft_mag_log(); // take the output of the fft

   for (byte i = 0; i < FFT_N/2; i++) {
     if(i<10 || i>20)
       fft_log_out[i] = 0;


After applying the filter like this:

if(i<10 || i>20)
       fft_log_out[i] = 0;

I then need to Inverse FFT data fft_log_out[].

I looked for an Inverse FFT function (in particular in http://wiki.openmusiclabs.com/wiki/FFTFunctions) but can't find it anywhere.

So how can I get the Inverse FFT in Arduino?

  • This is not what you want, it's just a suggestion. Why not using a discrete filter for that? That would be faster and "real time". May 30 '15 at 10:31

The inverse FFT can be obtained by making use of the forward transform:

for (int i = 0 ; i < 512 ; i += 2) {
  fft_input[i] =  (fft_input[i] >> 8);
  fft_input[i+1] = -(fft_input[i+1] >> 8);
// For complex data, you would then need to negate the imaginary part
// but we can skip this step since you have real data.

Note however that your filtering code has a few issues.

First, the results of the forward FFT are complex numbers which carry both magnitude and phase information. Using fft_mag_log only takes the magnitude, which alone is not sufficient for recovery of the original signal. You should thus use the complete FFT output left in fft_input array as input to your filtering code.

Second, the FFT of real valued data results in a spectrum with Hermitian symmetry. To get a real valued filtered output, you must preserve that symmetry. So, you should not completely zero out the values in the upper half of the spectrum:

for (byte i = 0; i < FFT_N; i+=2) {
  if (! ((i>=20 && i<=40) || (i>=FFT_N-40 && i<=FFT_N-20)))
    fft_input[i] = 0;
    fft_input[i+1] = 0;

Third, the filtering would be applied to each block of data independently of each other, always assuming that previous inputs were zeros. This typically results in discontinuities at the block boundaries. To avoid this, you should consider using the overlap-add method.

  • I want to filter specific 'frequency' but as i know [ fft_input[i] = 0 ] mean filter specific 'time' May 31 '15 at 5:03
  • Arduino put the output of the FFT back in fft_input, so fft_input[i]=0 after the FFT is run would filter specific frequency.
    – SleuthEye
    May 31 '15 at 10:54
  • i follow upper Inserver FFT code but i can't recovere original signal code :( Jun 2 '15 at 7:40
  • Note that full circle FFT involves scaling by 1/FFT_N. If you start off with weak signals they may get scaled down too much in the process. You could try to normalize your signal to use the full scale before the forward FFT, then scale them back down by the same amount after the inverse FFT.
    – SleuthEye
    Jun 2 '15 at 12:40

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