# Why are LASSO in sklearn (python) and matlab statistical package different?

I am using `LaasoCV` from `sklearn` to select the best model is selected by cross-validation. I found that the cross validation gives different result if I use sklearn or matlab statistical toolbox.

I used `matlab` and replicate the example given in http://www.mathworks.se/help/stats/lasso-and-elastic-net.html to get a figure like this Then I saved the `matlab` data, and tried to replicate the figure with `laaso_path` from `sklearn`, I got Although there are some similarity between these two figures, there are also certain differences. As far as I understand parameter `lambda` in `matlab` and `alpha` in `sklearn` are same, however in this figure it seems that there are some differences. Can somebody point out which is the correct one or am I missing something? Further the coefficient obtained are also different (which is my main concern).

Matlab Code:

``````rng(3,'twister') % for reproducibility
X = zeros(200,5);
for ii = 1:5
X(:,ii) = exprnd(ii,200,1);
end
r = [0;2;0;-3;0];
Y = X*r + randn(200,1)*.1;

save randomData.mat % To be used in python code

[b fitinfo] = lasso(X,Y,'cv',10);
lassoPlot(b,fitinfo,'plottype','lambda','xscale','log');

disp('Lambda with min MSE')
fitinfo.LambdaMinMSE
disp('Lambda with 1SE')
fitinfo.Lambda1SE
disp('Quality of Fit')
lambdaindex = fitinfo.Index1SE;
fitinfo.MSE(lambdaindex)
disp('Number of non zero predictos')
fitinfo.DF(lambdaindex)
disp('Coefficient of fit at that lambda')
b(:,lambdaindex)
``````

Python Code:

``````import scipy.io
import numpy as np
import pylab as pl
from sklearn.linear_model import lasso_path, LassoCV

data=scipy.io.loadmat('randomData.mat')
X=data['X']
Y=data['Y'].flatten()

model = LassoCV(cv=10,max_iter=1000).fit(X, Y)
print 'alpha', model.alpha_
print 'coef', model.coef_

eps = 1e-2 # the smaller it is the longer is the path
models = lasso_path(X, Y, eps=eps)
alphas_lasso = np.array([model.alpha for model in models])
coefs_lasso = np.array([model.coef_ for model in models])

pl.figure(1)
ax = pl.gca()
ax.set_color_cycle(2 * ['b', 'r', 'g', 'c', 'k'])
l1 = pl.semilogx(alphas_lasso,coefs_lasso)
pl.gca().invert_xaxis()
pl.xlabel('alpha')
pl.show()
``````
• I can just say I recall similar findings when working on real data. The Matlab results were different and significantly better. I didn't explore very deeply what this problem stems from, though. – Bitwise Oct 5 '12 at 12:45

## 4 Answers

I do not have matlab but be careful that the value obtained with the cross--validation can be unstable. This is because it influenced by the way you subdivide the samples.

Even if you run 2 times the cross-validation in python you can obtain 2 different results. consider this example :

``````kf=sklearn.cross_validation.KFold(len(y),n_folds=10,shuffle=True)
cv=sklearn.linear_model.LassoCV(cv=kf,normalize=True).fit(x,y)
print cv.alpha_
kf=sklearn.cross_validation.KFold(len(y),n_folds=10,shuffle=True)
cv=sklearn.linear_model.LassoCV(cv=kf,normalize=True).fit(x,y)
print cv.alpha_

0.00645093258722
0.00691712356467
``````

it's possible that `alpha = lambda / n_samples`
where `n_samples = X.shape` in scikit-learn

another remark is that your path is not very piecewise linear as it could/should be. Consider reducing the tol and increasing max_iter.

hope this helps

• I guess the issue is more than normalization. I tried the above one and still got different curves. Further, the coefficients obtained by cross validation is very different. – imsc Oct 7 '12 at 15:53
• This still looks like a parameterization issue to me: the 2 curves looks similar but shifted on the X axis. A rescaling on the alpha in scikit-learn taken in the log space can cause this. The parameterization used in scikit-learn is given in the documentation. You can also generate more data from the same distribution and compute a regression score (e.g. the coefficient of determination r^2 or the RMSE) and check that the optimal value of alpha is found close to the cross validated value of alpha. – ogrisel Oct 14 '12 at 9:44
• @imsc have you tried with `alpha = lambda / (2 * X.shape)`? – ogrisel Oct 17 '12 at 8:09

I know this is an old thread, but:

I'm actually working on piping over to `LassoCV` from `glmnet` (in R), and I found that `LassoCV` doesn't do too well with normalizing the X matrix first (even if you specify the parameter `normalize = True`).

Try normalizing the X matrix first when using LassoCV.

If it is a pandas object,

``````(X - X.mean())/X.std()
``````

It seems you also need to multiple alpha by 2

Though I am unable to figure out what is causing the problem, there is a logical direction in which to continue.

These are the facts:

• Mathworks have selected an example and decided to include it in their documentation
• Your matlab code produces exactly the result as the example.
• The alternative does not match the result, and has provided inaccurate results in the past

This is my assumption:

• The chance that mathworks have chosen to put an incorrect example in their documentation is neglectable compared to the chance that a reproduction of this example in an alternate way does not give the correct result.

The logical conclusion: Your matlab implementation of this example is reliable and the other is not. This might be a problem in the code, or maybe in how you use it, but either way the only logical conclusion would be that you should continue with Matlab to select your model.

• This is a very weak argument to advertise one technology over another. sklearn also provide exemples. Would it be reproducible by matlab code ? Actually LASSO is more like a class of solver than a precisely defined algorithm. So it is more probable that the algorithm slightly differ. Stating that scikit-learn is not reliable based on your arguments is quite harsh. – Nicolas Barbey Oct 12 '12 at 11:49
• I did not want to imply this, i have rephrased my answer slightly to be more clear. – Dennis Jaheruddin Oct 12 '12 at 14:01
• Thanks for the answer. `scikit-learn` is indeed a well implemented module. However the documentation and examples are still lacking which cause the above problem. I could solve the issue by proper normalization. – imsc Oct 15 '12 at 11:46