I'm an experienced software engineer with some minor college DSP knowledge. I'm working on a smartphone application to process signal data, such as from the microphone (sampled at 44100 Hz) and the accelerometer (sampled at 32-50 Hz). My applications would be, for example, pitch detectors and so forth.
I want to implement a low-pass filter (LPF) on the phone to remove aliased frequencies, particularly for the accelerometer, which has a low sampling rate. However, I am finding a contradiction when trying to apply the fast FFT-based convolution method. Any help would be appreciated.
Here is my line of reasoning:
I am reading a signal, and I want use a LPF to do anti-aliasing (remove aliased frequencies).
To implement the LPF on my smartphone, I choose to apply an FIR filter (namely, a windowed sinc function) to the time-domain signal. Let x[n] be my signal and f[n] be the coefficients of my filter kernel. So I want to perform convolution between x[n] and f[n], where x[n] is of length N (typically 512) and f[n] is of length M (typically 256).
I implemented a simple 1D convolution on my smartphone (Android and iPhone). The algorithm is the typical nested loop version and runs in O(N M). It is running too slowly on the smartphone for N=512 and M=256.
I then looked at the fast convolution algorithm that uses FFTs and runs in O(N lgN). Specifically, the filtered signal is from: filtered x[n] = IFFT(FFT(x) .* FFT(f)), where FFT is the fft, IFFT is the inverse FFT, and .* is element-by-element multiplication of two arrays.
However, I find a contradiction in that process: IFFT(FFT(x) .* FFT(f)). This requires that I take the FFT of x[n], but x[n] may have aliased frequencies. This is exactly my initial problem from step 1!
So, how can I resolve this contradiction? How can I use fast convolution to implement a LPF if the fast convolution internally requires a LPF?
NOTE: I've been told by some EE guys that some microphones have a hardware-based LPF built in, but I cannot be sure with my smartphone's microphone or the accelerometer.