# How to fit a gaussian to data in matlab/octave?

I have a set of frequency data with peaks to which I need to fit a Gaussian curve and then get the full width half maximum from. The FWHM part I can do, I already have a code for that but I'm having trouble writing code to fit the Gaussian.

Does anyone know of any functions that'll do this for me or would be able to point me in the right direction? (I can do least squares fitting for lines and polynomials but I can't get it to work for gaussians)

Also it would be helpful if it was compatible with both Octave and Matlab as I have Octave at the moment but don't get access to Matlab until next week.

Any help would be greatly appreciated!

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Do you have a single peak (only 1 Gaussian)? Or multiple peaks (multiple, overlapping Guassians)? –  Rody Oldenhuis Nov 8 '12 at 14:14
It's just a single peak per file. –  user1806676 Nov 8 '12 at 14:19
If it's just one peak, take the mean and standard-dev of the numbers and that defines your sample normal distribution. Have you tried that? Otherwise, if you have the stats toolbox, use normfit(). –  Justin Nov 8 '12 at 14:23
@Justin: Your first statement is wrong. If I have a bunch of data points around `x=-100`, with `y`-values corresponding to the standard normal there, and a bunch of similar values around `x=-2`, the mean of all those points will obviously not be zero, and the standard deviation will obviously not be unity. –  Rody Oldenhuis Nov 8 '12 at 14:52

Fitting a single 1D Gaussian directly is a non-linear fitting problem. You'll find ready-made implementations here, or here, or here for 2D, or here (if you have the statistics toolbox) (have you heard of Google? :)

Anyway, there might be a simpler solution. If you know for sure your data `y` will be well-described by a Gaussian, and is reasonably well-distributed over your entire `x`-range, you can linearize the problem (these are equations, not statements):

``````   y = 1/(σ·√(2π)) · exp( -½ ( (x-μ)/σ )² )
ln y = ln( 1/(σ·√(2π)) ) - ½ ( (x-μ)/σ )²
= Px² + Qx + R
``````

where the substitutions

``````P = -1/(2σ²)
Q = +2μ/(2σ²)
R = ln( 1/(σ·√(2π)) ) - ½(μ/σ)²
``````

have been made. Now, solve for the linear system `Ax=b` with (these are Matlab statements):

``````% design matrix for least squares fit
xdata = xdata(:);
A = [xdata.^2,  xdata,  ones(size(xdata))];

b = log(y(:));

% least-squares solution for x
x = A\b;
``````

The vector `x` you found this way will equal

``````x == [P Q R]
``````

which you then have to reverse-engineer to find the mean μ and the standard-deviation σ:

``````mu    = -x(2)/x(1)/2;
sigma = sqrt( -1/2/x(1) );
``````

Which you can cross-check with `x(3) == R` (there should only be small differences).

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Thanks very much. I had only been able to find the first of the links via google and that wasn't working with my data, the second one works a treat though. Also thanks for the explanation/equations. :D –  user1806676 Nov 8 '12 at 14:53
@user1806676: I haven't tried the linearized approach, but at least the math is correct. You should do some experimenting and validating there. –  Rody Oldenhuis Nov 8 '12 at 14:54
Tried the linearized approach. Works well. –  Rodin Jan 15 at 9:29
+1. For linearizing and taking the anti-log after to find your coefficients. Good least squared error solution! –  rayryeng May 23 at 14:30

Perhaps this has the thing you are looking for? Not sure about compatability: http://www.mathworks.com/matlabcentral/fileexchange/11733-gaussian-curve-fit

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finally i found here that matlab has built in fit function, that can fit Gaussians too.

it look like that:

``````>> v=-30:30;
>> fit(v', exp(-v.^2)', 'gauss1')

ans =

General model Gauss1:
ans(x) =  a1*exp(-((x-b1)/c1)^2)
Coefficients (with 95% confidence bounds):
a1 =           1  (1, 1)
b1 =  -8.489e-17  (-3.638e-12, 3.638e-12)
c1 =           1  (1, 1)
``````
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