# STFT Clarification (FFT for real-time input)

I get how the DFT via correlation works, and use that as a basis for understanding the results of the FFT. If I have a discrete signal that was sampled at 44.1kHz, then that means if I were to take 1s of data, I would have 44,100 samples. In order to run the FFT on that, I would have to have an array of 44,100 and a DFT with N=44,100 in order to get the resolution necessary to detect a frequencies up to 22kHz, right? (Because the FFT can only correlate the input with sinusoidal components up to a frequency of N/2)

That's obviously a lot of data points and calculation time, and I have read that this is where the Short-time FT (STFT) comes in. If I then take the first 1024 samples (~23ms) and run the FFT on that, then take an overlapping 1024 samples, I can get the continuous frequency domain of the signal every 23ms. Then how do I interpret the output? If the output of the FFT on static data is N/2 data points with fs/(N/2) bandwidth, what is the bandwidth of the STFT's frequency output?

Here's an example that I ran in Mathematica:

100Hz sine wave at 44.1kHz sample rate: Then I run the FFT on only the first 1024 points: The frequency of interest is then at data point 3, which should somehow correspond to 100Hz. I think 44100/1024 = 43 is something like a scaling factor, which means that a signal with 1Hz in this little window will then correspond to a signal of 43Hz in the full data array. However, this would give me an output of 43Hz*3 = 129Hz. Is my logic correct but not my implementation?

• I think you are misunderstanding the DFT, FFT and STFT. You do not need N = 44100 to detect frequencies up to 22Khz, you get frequencies up to 22KHz with any N (i.e N can be 200, 2000 e.t.c).The variable N only affects the frequency resolution you get, not the maximum or minimum values of values of frequency. – KillaKem May 26 '15 at 19:55
• STFT is used for signals whose frequency spectrum changes over time like music. – KillaKem May 26 '15 at 19:56
• And I should say that I intend to use this for continuous input, like music or a microphone. – MrUser May 27 '15 at 8:49
• Yes @KillaKem. My question says that I would have to have N=44100 to detect a frequency of 22k. I should have said, "to detect single frequencies up to 22kHz". Thank you for clearing that up. I then realized that by applying your comment, the 29Hz error is probably because my resolution is not fine enough. When I take STFT of 4096 points I get 107.6. One could see that this would trend toward 100Hz as N increased. (I would accept your comment as the answer if you posted it.) Thanks again. – MrUser May 27 '15 at 9:14 