I'm using Libgdx library for do FFT from accelerometer signal in an Android app.

I need to have my signal normalized because I find the dot product of two signal and I want its max value 1.

With "**normalization**" i mean that the *Euclidean Norm* of signal is 1.
(Euclidean norm is square root of the sum of product of analogue components of vector. When I've found its value, for normalize signal I divide all components of vector by the norm value).

Dot product is in the frequency spectrum, so if I normalize the signal in time domain, the frequency spectrum representation is not euclidean normalized, then I'll do again the euclidean normalization.
(I consider already after the FFT the normalization by 1/N *scale factor*, I think it not influence my problem, maybe).

Which are differences if I do Euclidean Normalization before and after FFT, or I do it only after FFT?

EDIT 1: Consider also that FFT in Libgdx library is Complex DFT, and I've real signal in input than the output signal is symmetric for 0 to (N/2)-1 and N/2 to N. I verify that Parseval's Theorem is verified if I apply no window (like Hamming's window). So, if I use 0 to N/2-1 components of signal, will I obtain a dot product between 0 and 1?