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I'm fairly new to signal processing, so please bear with me. I'm trying to implement a bandpass filter to apply to an audio recording obtained from an iPad. The recording has been converted to a Float32 pointer using ExtFile functions and AudioBufferList. The sampling rate is 44100Hz. The recording is about 9 seconds long (that's about 396900 samples) and contains a 2-6kHz chirp and some ambient noise. I need to bandpass filter the recording around the frequency range 2-6kHz in order to find at what point in time the chirp occurs. I have referred to the following resources to create a bandpass filter:

My question is, can I simply pass in the array of float values for the recording to the bandpass filter above? I have tried this, but I'm not sure if it's working, since it seems to simply decrease the value of every single value in the array. What should I expect to see after passing the recording th

However, I've seen some resources say that I first need to convert the values from time-domain to frequency-domain using a FFT. I've tried the following code to do this using some vDSP functions:

- (Float32 *)calculateFFT
    // Acquired from

    int numSamples = _recordingLength; //~9 seconds * 44100Hz ~= 396900 samples

    // Setup the length
    vDSP_Length log2n = log2f(numSamples);

    // Calculate the weights array. This is a one-off operation.
    FFTSetup fftSetup = vDSP_create_fftsetup(log2n, FFT_RADIX2);

    // For an FFT, numSamples must be a power of 2, i.e. is always even
    int nOver2 = numSamples/2;

    // Populate *window with the values for a hamming window function
    float *window = (float *)malloc(sizeof(float) * numSamples);
    vDSP_hamm_window(window, numSamples, 0);
    // Window the samples
    vDSP_vmul(_recordingSamples, 1, window, 1, _recordingSamples, 1, numSamples);

    // Define complex buffer
    A.realp = (float *) malloc(nOver2*sizeof(float));
    A.imagp = (float *) malloc(nOver2*sizeof(float));

    // Pack samples:
    // C(re) -> A[n], C(im) -> A[n+1]
    vDSP_ctoz((COMPLEX*)_recordingSamples, 2, &A, 1, numSamples/2);

    //Perform a forward FFT using fftSetup and A
    //Results are returned in A
    vDSP_fft_zrip(fftSetup, &A, 1, log2n, FFT_FORWARD);

    //Convert COMPLEX_SPLIT A result to magnitudes
    Float32 *amp = new Float32[numSamples];
    amp[0] = A.realp[0]/(numSamples*2);
    for(int i=1; i<numSamples; i++) {
        //printf("%f ",amp[i]);

    return amp;

But I don't understand what is being returned from this function. If I do need to apply a FFT before passing the recording to the filter, what needs to be returned from the calculateFFT function and then passed to the filter?

Thanks in advance.

share|improve this question
It is possible to perform filtering in the frequency-domain (which would likely require the use of FFT), but the filter implementation you listed perform filtering in the time-domain, that is it would use the float audio recording samples. The result would depend on your filter design parameters. – SleuthEye Jun 11 '14 at 15:07
@SleuthEye Okay, so the NVDSP functions filter in the time-domain, so I don't need to use FFT. I guess the recording float array must contain some information about the frequency then if the bandpass filter can filter it given a range of frequencies? – sonofjack3 Jun 11 '14 at 16:22
NVDSP transforms the Fc/Q parameters into time-domain coefficients. – SleuthEye Jun 11 '14 at 16:27
@SleuthEye I'm sorry if this is a stupid question, but will filtering in the time-domain produce the results I'm looking for (ie: filter out areas of background noise and not areas where the chirp is playing)? – sonofjack3 Jun 11 '14 at 16:54
Processing the time-domain samples will have an effect on the frequency content. If the background noise is not-overlapping from the chirp (eg. noise in 8-15kHz range), and the filter parameters are selected carefully, then the noise can be filtered out. If the noise and chirp overlap in time and frequency, then it would be harder to filter out noise (although removing the non-overlapping part can still make your chirp easier to identify). – SleuthEye Jun 11 '14 at 19:20

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