## TL;DR (summary)

It's very hard to find online examples of `fft`

usage with Matlab that normalise the amplitude/power values correctly. This is crucial if you're going to compare these values across different signals with different lengths. This is most often a problem for real-valued inputs, because a single-sided spectrum is usually extracted in that case, and therefore changes in magnitude should be manually applied when computing the amplitude or power values. You can find a gist on GitHub here (please let me know of any bugs).

The take home messages are:

- Do NOT normalise the DFT coefficients directly (eg don't write
`Y = fft(x)/L`

); - If you use an n-points transform (eg
`fft(x,nfft)`

), then the normaliser is`nfft`

and not`numel(x)`

; - If you extract a single-sided spectrum, you need to adjust amplitude/power values depending on which correspond to conjugate pairs DFT coefficients;
- If you extract a single-sided spectrum, you should compute the amplitude and power separately (ie don't compute the power from the amplitudes).

## Question

My question is similar to, but more general than this post, and I think there is a mistake in there regarding normalisation, with the newest version of Matlab (2015) anyway. I hesitated to post this on CodeReview SE, if you think it would be more appropriate let me know in the comments.

I would like to **validate the following code** of a Fourier transform using Matlab's `fft`

, because I have found conflicting sources of information on the web, including in the Matlab help itself, and I have been unable to verify Parseval's theorem with certain such "recipes" (including with answers coming from the MathWorks team, see below), especially those extracting single-sided spectra for real inputs.

For instance, the amplitude-doubling commonly found online to account for the symmetric spectra of real-valued signals when extracting positive frequencies only seems to be wrong (Parseval's theorem fails), and instead it seems to be necessary to use a square-root of two coefficient in Matlab (I don't know why). Some people also seem to normalise the DFT coefficients directly like `Y = fft(X)/L`

, but I think this is confusing and should be discouraged; the amplitude is defined as the modulus of the complex DFT coefficient divided by the signal length, the coefficients themselves should not be divided. Once validated I intend to post this code as a gist on GitHub.

```
function [frq,amp,phi] = fourier_transform( time, vals )
% FOURIER_TRANSFORM computes the Fast Fourier Transform of a given time-series.
%
% [freq,amp,phi] = fourier_transform(time,vals)
%
% Inputs:
%
% time - Nx1 column vector of equally-spaced timepoints (if not, input will be resampled).
% vals - NxM matrix of real- or complex-valued observations at previous timepoints.
%
% Outputs:
%
% frq - column vector of frequencies in Hz
% amp - corresponding matrix of amplitudes for each frequency (row) and signal (column)
% phi - corresponding unwrapped phase for each frequency (row) and signal (column)
%
% Note:
% To compute the power from the output amplitude, you need to multiply by the number of timepoints:
% power = numel(time) * amp.^2;
%
% References:
% https://en.wikipedia.org/wiki/Discrete_Fourier_transform
% make sure input time-series is uniformly sampled
assert( iscolumn(time), 'Input time should be a column vector.' );
assert( ismatrix(vals) && size(vals,1) == numel(time), 'Input values should be a matrix with same number of rows than of timepoints.' );
if std(diff(time)) > 1e-6
warning('Input time-course does not appear to be uniformly sampled. Resampling before continuing.');
[vals,time] = resample(vals,time);
end
% sampling information
nt = numel(time);
dt = time(2)-time(1);
fs = 1/dt;
df = fs/nt;
% complex spectrum coefficients
coef = fft(vals);
% real input
if isreal(vals)
% extract one-sided spectrum (spectrum is symmetric)
nfft = floor( nt/2 + 1 ); % eg 8 -> 5, and 7 -> 4
coef = coef( 1:nfft, : );
frq = (0:nfft-1)*df;
% correct amplitude values to account for previous extraction
fac = sqrt(2);
amp = fac*abs(coef)/nt;
amp(1,:) = amp(1,:)/fac; % .. except for the DC component
if mod(nt,2) == 0
amp(end,:) = amp(end,:)/fac; % .. and for the Nyquist frequency (only if nt is even)
end
% complex input
else
% shift the spectrum to center frequencies around 0
coef = fftshift( coef );
frq = fftshift( (0:nt-1)*df );
amp = abs(coef)/nt;
end
% make sure frq is a column vector and compute phases
frq = frq(:);
phi = unwrap(angle(coef));
end
```

## Example use

```
>> fs=1e3; t=transpose(0:1/fs:10); nt=numel(t); X=rand(nt,1);
>> [frq,amp,phi] = fourier_transform( t, X );
>> sum( abs(X).^2 ) - nt*sum( amp.^2 ) % Parseval's theorem
ans =
-2.7285e-11
```

## Wrong example 1

From Matlab's own example, and posted on SO:

```
>> Fs = 1000; % Sampling frequency
T = 1/Fs; % Sample time
L = 1000; % Length of signal
t = (0:L-1)*T; % Time vector
x = 0.7*sin(2*pi*50*t) + sin(2*pi*120*t);
y = x + 2*randn(size(t)); % Sinusoids plus noise
NFFT = 2^nextpow2(L); % Next power of 2 from length of y
Y = fft(y,NFFT)/L;
f = Fs/2*linspace(0,1,NFFT/2+1);
>> sum(abs(y).^2) - NFFT*sum(abs(Y).^2) % Parseval's theorem
ans =
-220.4804
```

*Problem and solution:*

Comes from the normalisation in the line `Y = fft(y,NFFT)/L`

.
This should be instead:

```
>> Y = fft(y,NFFT);
Ya = abs(Y)/NFFT; % correctly normalised amplitudes
sum(abs(y).^2) - NFFT*sum(Ya.^2) % Parseval's theorem
```

## Wrong example 2

From the MathWorks team's own clarification post:

```
>> Fs = 1000; % Sampling frequency
T = 1/Fs; % Sample time
L = 1000; % Length of signal
t = (0:L-1)*T; % Time vector
% Sum of a 50 Hz sinusoid and a 120 Hz sinusoid
x = 0.7*sin(2*pi*50*t) + sin(2*pi*120*t);
y = x + 2*randn(size(t)); % Sinusoids plus noise
NFFT = 2^nextpow2(L); % Next power of 2 from length of y
Y = fft(y,NFFT)/L;
f = Fs/2*linspace(0,1,NFFT/2+1);
NumUniquePts = ceil((NFFT+1)/2);
Y=Y(1:NumUniquePts);
MX=2*abs(Y);
MX(1)=MX(1)/2; % DC component
if ~rem(NFFT,2) % when NFFT is even, Y(1+Y/2) is the Nyquist frequency component of x, and needs to make sure it is unique.
MX(length(MX))=MX(length(MX))/2;
end
>> sum( abs(y).^2 ) - NFFT*sum( MX.^2 )
ans =
-5.3812e+03
```

*Problem and solution:*

Normalisation again. Replace `Y = fft(y,NFFT)/L;`

by `Y = fft(y,NFFT)`

, and supposedly `MX=2*abs(Y);`

by `MX=2*abs(Y)/NFFT;`

. But here the amplitude doubling problem appears; the correction factor seems to be `sqrt(2)`

and not `2`

.

## Wrong example 3

Found as an answer on MatlabCentral:

```
>> Fs = 1000; % Sampling frequency
T = 1/Fs; % Sample time
L = 1000; % Length of signal
t = (0:L-1)*T; % Time vector
x = 0.7*sin(2*pi*Fs/8*t) + sin(2*pi*Fs/4*t);
NFFT = 2^nextpow2(L); % Next power of 2 from length of y
Y = fft(x,NFFT)/L;
f = Fs/2*linspace(0,1,NFFT/2+1);
>> sum( abs(x).^2 ) - NFFT*sum( abs(Y).^2 )
ans =
-36.1891
```

*Problem and solution:*

As in the first example, normalisation problem. Write instead:

```
Y = fft(x,NFFT);
Ya = abs(Y)/NFFT;
sum( abs(x).^2 ) - NFFT*sum( abs(Ya).^2 )
```

Worng example 1, you can (in the final line) replace`L`

by`L^2 /NFFT`

you get the correct result. As far as I remember Matlabs`fft/ifft`

do not scale the values as it is usually done. I suggest comparing the formula given in`help fft`

with the result of`fft`

. – flawr Feb 3 '16 at 14:48`Y = fft(X)/L`

. That's a bad idea, and even anerrorwhen using the N-points transform`Y = fft(X,N)/L`

. It should be`Y = fft(X,N)/N`

instead, although again I would discourage writing this. Additionally, this does not answer the question of what the discrete amplitudes and power should be for the single-sided case. – Sheljohn Feb 3 '16 at 14:52