# Difference between fitting algorithms in scipy

I have a question about the fit algorithms used in scipy. In my program, I have a set of x and y data points with y errors only, and want to fit a function

``````f(x) = (a[0] - a[1])/(1+np.exp(x-a[2])/a[3]) + a[1]
``````

to it.

The problem is that I get absurdly high errors on the parameters and also different values and errors for the fit parameters using the two fit scipy fit routines scipy.odr.ODR (with least squares algorithm) and scipy.optimize. I'll give my example:

Fit with scipy.odr.ODR, fit_type=2

``````Beta: [ 11.96765963 68.98892582 100.20926023 0.60793377]
Beta Std Error: [ 4.67560801e-01 3.37133614e+00 8.06031988e+04 4.90014367e+04]
Beta Covariance: [[ 3.49790629e-02 1.14441187e-02 -1.92963671e+02 1.17312104e+02]
[ 1.14441187e-02 1.81859542e+00 -5.93424196e+03 3.60765567e+03]
[ -1.92963671e+02 -5.93424196e+03 1.03952883e+09 -6.31965068e+08]
[ 1.17312104e+02 3.60765567e+03 -6.31965068e+08 3.84193143e+08]]
Residual Variance: 6.24982731975
Inverse Condition #: 1.61472215874e-08
Reason(s) for Halting:
Sum of squares convergence
``````

and then the fit with scipy.optimize.leastsquares:

Fit with scipy.optimize.leastsq

``````beta: [ 11.9671859 68.98445306 99.43252045 1.32131099]
Beta Std Error: [0.195503 1.384838 34.891521 45.950556]
Beta Covariance: [[ 3.82214235e-02 -1.05423284e-02 -1.99742825e+00 2.63681933e+00]
[ -1.05423284e-02 1.91777505e+00 1.27300761e+01 -1.67054172e+01]
[ -1.99742825e+00 1.27300761e+01 1.21741826e+03 -1.60328181e+03]
[ 2.63681933e+00 -1.67054172e+01 -1.60328181e+03 2.11145361e+03]]
Residual Variance: 6.24982904455 (calulated by me)
``````

My Point is the third fit parameter: The results are

scipy.odr.ODR, fit_type=2: `C = 100.209 +/- 80600`

scipy.optimize.leastsq: `C = 99.432 +/- 12.730`

I don't know why the first error is so much higher. Even better: If I put exactly the same data points with errors into Origin 9 I get C = x0 = 99,41849 +/- 0,20283

and again exactly the same data into c++ ROOT Cern C = 99.85+/- 1.373

even though I used exactly the same initial variables for ROOT and Python. Origin doesn't need any.

Do you have any clue why this happens and which is the best result?

I added the code for you at pastebin:

• Data
• C++ code
• Python code: `http://pastebin.com/jZVyzMkS`

Thank you for helping!

EDIT: here's the plot related to SirJohnFranklins post:

-
Could you plot on the same graph the fits and errors obtained by (1) `scipy.odr` with x and y errors, and (2) `ROOT` with x and y errors. Also, how does `ROOT` determine what relative weighting to give to x and y errors, given that they are measured in different units? In `scipy.odr`, `sx` and `sy` are converted to weights by dividing 1.0 by their squares - does `ROOT` do the same? –  ali_m Jun 30 '13 at 23:27

Did you actually try plotting the `ODR` and `leastsq` fits side by side? They look basically identical:

Consider what the parameters correspond to - the step function described by `beta[0]` and `beta[1]`, the initial and final values, explains by far the majority of the variance in your data. By contrast, small changes in `beta[2]` and `beta[3]`, the inflexion point and slope, will have comparatively little effect on the overall shape of the curve and therefore the residual variance for the fit. It's therefore no surprise that these parameters have high standard errors, and are fitted slightly differently by the two algorithms.

The overall greater standard errors reported by `ODR` are due to the fact that this model incorporates errors in the y-values whereas the ordinary least squares fit does not - errors in the measured y-values ought to reduce our confidence in the estimated fit parameters.

-

(Sadly, i can't upload the fit, because I need more reputation. I'll give the plot to Captain Sandwich, so he can upload it for me.)

I'm in the same workgroup as the person who started the thread, but I did this plot.

So, I added x-errors on the data, because I was not that far the last time. The error obtained through the ODR is still absurdly high (4.18550164e+04 on beta[2]). In the plot, I show you what the FIT from [ROOT Cern][2] gives, now with x and y error. Here, x0 is the beta[2].

The red and the green curve have a different beta, the left one minus the error of the fit of 3.430 obtained by ROOT and the right one plus the error. I think this makes totally sense, much more, than the error of 0.2 given by the fit of Origin 9 (which can only handle y-errors, I think) or the error of about 40k given by the ODR which also includes x and y errors.

Maybe, because ROOT is mostly used by astrophysicists who need very roubust fitting algorithms, it can handle much more difficult fits, but I don't know enough about the robustness of fitting algorithms.

-
I really don't think there is any issue with the robustness of the fits - all of the different algorithms you've tried seem to give sensible estimates for the model parameters. The only question in my mind is about ODR's reporting of the standard errors on the fit parameters. –  ali_m Jun 30 '13 at 23:47