Parameters that are not directly learnt within estimators can be set by searching a parameter space for the best Cross-validation: evaluating estimator performance score. Typical examples include C, kernel and gamma for Support Vector Classifier, alpha for Lasso, etc.
Any parameter provided when constructing an estimator may be optimized in this manner. Specifically, to find the names and current values for all parameters for a given estimator, use:
estimator.get_params()
Such parameters are often referred to as hyperparameters (particularly in Bayesian learning), distinguishing them from the parameters optimised in a machine learning procedure.
A search consists of:
Some models allow for specialized, efficient parameter search strategies, outlined below. Two generic approaches to sampling search candidates are provided in scikit-learn: for given values, GridSearchCV exhaustively considers all parameter combinations, while RandomizedSearchCV can sample a given number of candidates from a parameter space with a specified distribution. After describing these tools we detail best practice applicable to both approaches.
The grid search provided by GridSearchCV exhaustively generates candidates from a grid of parameter values specified with the param_grid parameter. For instance, the following param_grid:
param_grid = [ {'C': [1, 10, 100, 1000], 'kernel': ['linear']}, {'C': [1, 10, 100, 1000], 'gamma': [0.001, 0.0001], 'kernel': ['rbf']}, ]
specifies that two grids should be explored: one with a linear kernel and C values in [1, 10, 100, 1000], and the second one with an RBF kernel, and the cross-product of C values ranging in [1, 10, 100, 1000] and gamma values in [0.001, 0.0001].
The GridSearchCV instance implements the usual estimator API: when “fitting” it on a dataset all the possible combinations of parameter values are evaluated and the best combination is retained.
Examples:
While using a grid of parameter settings is currently the most widely used method for parameter optimization, other search methods have more favourable properties. RandomizedSearchCV implements a randomized search over parameters, where each setting is sampled from a distribution over possible parameter values. This has two main benefits over an exhaustive search:
Specifying how parameters should be sampled is done using a dictionary, very similar to specifying parameters forGridSearchCV. Additionally, a computation budget, being the number of sampled candidates or sampling iterations, is specified using the n_iter parameter. For each parameter, either a distribution over possible values or a list of discrete choices (which will be sampled uniformly) can be specified:
[{'C': scipy.stats.expon(scale=100), 'gamma': scipy.stats.expon(scale=.1), 'kernel': ['rbf'], 'class_weight':['auto', None]}]
This example uses the scipy.stats module, which contains many useful distributions for sampling parameters, such as expon,gamma, uniform or randint. In principle, any function can be passed that provides a rvs (random variate sample) method to sample a value. A call to the rvs function should provide independent random samples from possible parameter values on consecutive calls.
Warning
The distributions in scipy.stats do not allow specifying a random state. Instead, they use the global numpy random state, that can be seeded via np.random.seed or set using np.random.set_state.
For continuous parameters, such as C above, it is important to specify a continuous distribution to take full advantage of the randomization. This way, increasing n_iter will always lead to a finer search.
Examples:
References:
By default, parameter search uses the score function of the estimator to evaluate a parameter setting. These are thesklearn.metrics.accuracy_score for classification and sklearn.metrics.r2_score for regression. For some applications, other scoring functions are better suited (for example in unbalanced classification, the accuracy score is often uninformative). An alternative scoring function can be specified via the scoring parameter to GridSearchCV,RandomizedSearchCV and many of the specialized cross-validation tools described below. See The scoring parameter: defining model evaluation rules for more details.
Pipeline: chaining estimators describes building composite estimators whose parameter space can be searched with these tools.
Model selection by evaluating various parameter settings can be seen as a way to use the labeled data to “train” the parameters of the grid.
When evaluating the resulting model it is important to do it on held-out samples that were not seen during the grid search process: it is recommended to split the data into a development set (to be fed to the GridSearchCV instance) and anevaluation set to compute performance metrics.
This can be done by using the cross_validation.train_test_split utility function.
GridSearchCV and RandomizedSearchCV evaluate each parameter setting independently. Computations can be run in parallel if your OS supports it, by using the keyword n_jobs=-1. See function signature for more details.
Some parameter settings may result in a failure to fit one or more folds of the data. By default, this will cause the entire search to fail, even if some parameter settings could be fully evaluated. Setting error_score=0 (or =np.NaN) will make the procedure robust to such failure, issuing a warning and setting the score for that fold to 0 (or NaN), but completing the search.
Some models can fit data for a range of value of some parameter almost as efficiently as fitting the estimator for a single value of the parameter. This feature can be leveraged to perform a more efficient cross-validation used for model selection of this parameter.
The most common parameter amenable to this strategy is the parameter encoding the strength of the regularizer. In this case we say that we compute the regularization path of the estimator.
Here is the list of such models:
linear_model.ElasticNetCV([l1_ratio, eps, ...]) | Elastic Net model with iterative fitting along a regularization path |
linear_model.LarsCV([fit_intercept, ...]) | Cross-validated Least Angle Regression model |
linear_model.LassoCV([eps, n_alphas, ...]) | Lasso linear model with iterative fitting along a regularization path |
linear_model.LassoLarsCV([fit_intercept, ...]) | Cross-validated Lasso, using the LARS algorithm |
linear_model.LogisticRegressionCV([Cs, ...]) | Logistic Regression CV (aka logit, MaxEnt) classifier. |
linear_model.MultiTaskElasticNetCV([...]) | Multi-task L1/L2 ElasticNet with built-in cross-validation. |
linear_model.MultiTaskLassoCV([eps, ...]) | Multi-task L1/L2 Lasso with built-in cross-validation. |
linear_model.OrthogonalMatchingPursuitCV([...]) | Cross-validated Orthogonal Matching Pursuit model (OMP) |
linear_model.RidgeCV([alphas, ...]) | Ridge regression with built-in cross-validation. |
linear_model.RidgeClassifierCV([alphas, ...]) | Ridge classifier with built-in cross-validation. |
Some models can offer an information-theoretic closed-form formula of the optimal estimate of the regularization parameter by computing a single regularization path (instead of several when using cross-validation).
Here is the list of models benefitting from the Aikike Information Criterion (AIC) or the Bayesian Information Criterion (BIC) for automated model selection:
linear_model.LassoLarsIC([criterion, ...]) | Lasso model fit with Lars using BIC or AIC for model selection |
When using ensemble methods base upon bagging, i.e. generating new training sets using sampling with replacement, part of the training set remains unused. For each classifier in the ensemble, a different part of the training set is left out.
This left out portion can be used to estimate the generalization error without having to rely on a separate validation set. This estimate comes “for free” as no additional data is needed and can be used for model selection.
This is currently implemented in the following classes:
ensemble.RandomForestClassifier([...]) | A random forest classifier. |
ensemble.RandomForestRegressor([...]) | A random forest regressor. |
ensemble.ExtraTreesClassifier([...]) | An extra-trees classifier. |
ensemble.ExtraTreesRegressor([n_estimators, ...]) | An extra-trees regressor. |
ensemble.GradientBoostingClassifier([loss, ...]) | Gradient Boosting for classification. |
ensemble.GradientBoostingRegressor([loss, ...]) | Gradient Boosting for regression. |