My question has to do with the physical meaning of the results of doing a spectral analysis of a signal, or of throwing the signal into an FFT and interpreting what comes out using a suitable numerical package,
- take a signal, say a time-varying voltage v(t)
- throw it into an FFT (you get back a sequence of complex numbers)
- now take the modulus (abs) and square the result, i.e. |fft(v)|^2.
So you now have real numbers on the y axis -- shall I call these spectral coefficients?
- using the sampling resolution, you follow a cookbook recipe and associate the spectral coefficients to frequencies.
- AT THIS POINT, you have a frequency spectrum g(w) with frequency on the x axis, but WHAT PHYSICAL UNITS on the y axis?
My understanding is that this frequency spectrum shows how much of the various frequencies are present in the voltage signal -- they are spectral coefficients in the sense that they are the coefficients of the sines and cosines of the various frequencies required to reconstitute the original signal.
So the first question is, what are the UNITS of these spectral coefficients?
The reason this matters is that spectral coefficients can be tiny and enormous, so I want to use a dB scale to represent them.
But to do that, I have to make a choice:
- Either I use the 20log10 dB conversion, corresponding to a field measurement, like voltage.
- Or I use the 10log10 dB conversion, corresponding to an energy measurement, like power.
Which scaling I use depends on what the units are.
Any light shed on this would be greatly appreciated!