Using some weights `w[k]`

, compute the sums

`yxlx`

over `w[k]*y[k]*x[k]*log2(x[k])`

and

`xlx2`

over `w[k]*sqr(x[k]*log2(x[k]))`

, where `sqr(u)=u*u`

.

Then the estimate for `c`

is `yxlx/xlx2`

.

One can chose the standard weights `w[k]=1`

or adapting weights

```
w[k]=1/( 1+sqr( x[k]*log2(x[k]) ) )
```

or even more adapting

```
w[k]=1/( 1+sqr( x[k]*log2(x[k]) ) +sqr( y[k] ) )
```

so that large values for x,y do not excessively influence the estimate. For some middle strategy take the square root of those expressions as weights.

Mathematics: These formulas result from the formulation of the estimation problem as a weighted least square problem

```
sum[ w(x,y)*(y-c*f(x))^2 ] over (x,y) in Data
```

which expands as

```
sum[ w(x,y)*y^2 ]
-2*c* sum[ w(x,y)*y*f(x) ]
+ c^2 * sum[ w(x,y)*f(x)^2 ] over (x,y) in Data
```

where the minimum is located at

```
c = sum[ w(x,y)*y*f(x) ] / sum[ w(x,y)*f(x)^2 ]
```

w(x,y) should be approximately inverse to the variance of the error at (x,y), so if you expect a uniform size of the error, then w(x,y)=1, if the error grows proportional to x and y, then w(x,y)=1/(1+x^2+y^2) or similar is a sensible choice.

`lsqcurvefit`

not working? Can you post some code and a subset of data? – craigim Dec 11 '13 at 17:49