I need some help confirming some basic DSP steps. I'm in the process of implementing some smartphone accelerometer sensor signal processing software, but I've not worked in DSP before.

My program collects accelerometer data in real time at 32 Hz. The output should be the principal frequencies of the signal.

My specific questions are:

From the real-time stream, I am collecting a 256-sample window with 50% overlap, as I've read in the literature. That is, I add in 128 samples at a time to fill up a 256-sample window. Is this a correct approach?

The first figure below shows one such 256-sample window. The second figure shows the sample window after I applied a Hann/Hamming window function. I've read that applying a window function is a typical approach, so I went ahead and did it. Should I be doing so?

The third window shows the power spectrum (?) from the output of an FFT library. I am really cobbling together bits and pieces I've read. Am I correct in understanding that the spectrum goes up to 1/2 the sampling rate (in this case 16 Hz, since my sampling rate is 32 Hz), and the value of each spectrum point is spectrum[i] = sqrt(real[i]^2 + imaginary[i]^2)? Is this right?

Assuming what I did in question 3 is correct, is my understanding right that the third figure shows principal frequencies of about 3.25 Hz and 8.25 Hz? I know from collecting the data that I was running at about 3 Hz, so the spike at 3.25 Hz seems right. So there must be some noise other other factors causing the (erroneous) spike at 8.25 Hz. Are there any filters or other methods I can use to smooth away this and other spikes? If not, is there a way to determine "real" spikes from erroneous spikes?

serious issuesince you are analyzing the absolute value of the acceleration. It's like analyzing the absolute value of a sine: you would get double the frequency plus some artifact frequencies. – toto2 Jul 22 '11 at 23:34