The model you give can be solved using simple methods:

```
% model function
f = @(a,b,c,x) 1./(a*x.^2+b*x+c);
% noise function
noise = @(z) 0.005*randn(size(z));
% parameters to find
a = +3;
b = +4;
c = -8;
% exmample data
x = -2:0.01:2; x = x + noise(x);
y = f(a,b,c, x); y = y + noise(y);
% create linear system Ax = b, with
% A = [x² x 1]
% x = [a; b; c]
% b = 1/y;
A = bsxfun(@power, x.', 2:-1:0);
A\(1./y.')
```

Result:

```
ans =
3.035753123094593e+00 % (a)
4.029749103502019e+00 % (b)
-8.038644874704120e+00 % (c)
```

This is possible because the model you give is a linear one, in which case the backslash operator will give the solution (the `1./y`

is a bit dangerous though...)

When fitting *non*-linear models, take a look at `lsqcurvefit`

(optimization toolbox), or you can write your own implementation using `fmincon`

(optimization toolbox), `fminsearch`

or `fminunc`

.

Also, if you happen to have the curve fitting toolbox, type `help curvefit`

and start there.

`fminunc`

and`fminsearch`

. – H.Muster Oct 19 '12 at 8:16