Logistic regression does not support imbalanced classification directly.
Instead, the training algorithm used to fit the logistic regression model must be modified to take the skewed distribution into account. This can be achieved by specifying a class weighting configuration that is used to influence the amount that logistic regression coefficients are updated during training.
The weighting can penalize the model less for errors made on examples from the majority class and penalize the model more for errors made on examples from the minority class. The result is a version of logistic regression that performs better on imbalanced classification tasks, generally referred to as costsensitive or weighted logistic regression.
In this tutorial, you will discover costsensitive logistic regression for imbalanced classification.
After completing this tutorial, you will know:
 How standard logistic regression does not support imbalanced classification.
 How logistic regression can be modified to weight model error by class weight when fitting the coefficients.
 How to configure class weight for logistic regression and how to grid search different class weight configurations.
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Tutorial Overview
This tutorial is divided into five parts; they are:
 Imbalanced Classification Dataset
 Logistic Regression for Imbalanced Classification
 Weighted Logistic Regression With ScikitLearn
 Grid Search Weighted Logistic Regression
Imbalanced Classification Dataset
Before we dive into the modification of logistic regression for imbalanced classification, let’s first define an imbalanced classification dataset.
We can use the make_classification() function to define a synthetic imbalanced twoclass classification dataset. We will generate 10,000 examples with an approximate 1:100 minority to majority class ratio.

... # define dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) 
Once generated, we can summarize the class distribution to confirm that the dataset was created as we expected.

... # summarize class distribution counter = Counter(y) print(counter) 
Finally, we can create a scatter plot of the examples and color them by class label to help understand the challenge of classifying examples from this dataset.

... # scatter plot of examples by class label for label, _ in counter.items(): row_ix = where(y == label)[0] pyplot.scatter(X[row_ix, 0], X[row_ix, 1], label=str(label)) pyplot.legend() pyplot.show() 
Tying this together, the complete example of generating the synthetic dataset and plotting the examples is listed below.
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# Generate and plot a synthetic imbalanced classification dataset from collections import Counter from sklearn.datasets import make_classification from matplotlib import pyplot from numpy import where # define dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # summarize class distribution counter = Counter(y) print(counter) # scatter plot of examples by class label for label, _ in counter.items(): row_ix = where(y == label)[0] pyplot.scatter(X[row_ix, 0], X[row_ix, 1], label=str(label)) pyplot.legend() pyplot.show() 
Running the example first creates the dataset and summarizes the class distribution.
We can see that the dataset has an approximate 1:100 class distribution with a little less than 10,000 examples in the majority class and 100 in the minority class.

Counter(0: 9900, 1: 100) 
Next, a scatter plot of the dataset is created showing the large mass of examples for the majority class (blue) and a small number of examples for the minority class (orange), with some modest class overlap.
Next, we can fit a standard logistic regression model on the dataset.
We will use repeated crossvalidation to evaluate the model, with three repeats of 10fold crossvalidation. The mode performance will be reported using the mean ROC area under curve (ROC AUC) averaged over repeats and all folds.

... # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # evaluate model scores = cross_val_score(model, X, y, scoring=‘roc_auc’, cv=cv, n_jobs=–1) # summarize performance print(‘Mean ROC AUC: %.3f’ % mean(scores)) 
Tying this together, the complete example of evaluated standard logistic regression on the imbalanced classification problem is listed below.
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# fit a logistic regression model on an imbalanced classification dataset from numpy import mean from sklearn.datasets import make_classification from sklearn.model_selection import cross_val_score from sklearn.model_selection import RepeatedStratifiedKFold from sklearn.linear_model import LogisticRegression # generate dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # define model model = LogisticRegression(solver=‘lbfgs’) # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # evaluate model scores = cross_val_score(model, X, y, scoring=‘roc_auc’, cv=cv, n_jobs=–1) # summarize performance print(‘Mean ROC AUC: %.3f’ % mean(scores)) 
Running the example evaluates the standard logistic regression model on the imbalanced dataset and reports the mean ROC AUC.
We can see that the model has skill, achieving a ROC AUC above 0.5, in this case achieving a mean score of 0.985.
This provides a baseline for comparison for any modifications performed to the standard logistic regression algorithm.
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Logistic Regression for Imbalanced Classification
Logistic regression is an effective model for binary classification tasks, although by default, it is not effective at imbalanced classification.
Logistic regression can be modified to be better suited for logistic regression.
The coefficients of the logistic regression algorithm are fit using an optimization algorithm that minimizes the negative log likelihood (loss) for the model on the training dataset.
 minimize sum i to n (log(yhat_i) * y_i + log(1 – yhat_i) * (1 – y_i))
This involves the repeated use of the model to make predictions followed by an adaptation of the coefficients in a direction that reduces the loss of the model.
The calculation of the loss for a given set of coefficients can be modified to take the class balance into account.
By default, the errors for each class may be considered to have the same weighting, say 1.0. These weightings can be adjusted based on the importance of each class.
 minimize sum i to n (w0 * log(yhat_i) * y_i + w1 * log(1 – yhat_i) * (1 – y_i))
The weighting is applied to the loss so that smaller weight values result in a smaller error value, and in turn, less update to the model coefficients. A larger weight value results in a larger error calculation, and in turn, more update to the model coefficients.
 Small Weight: Less importance, less update to the model coefficients.
 Large Weight: More importance, more update to the model coefficients.
As such, the modified version of logistic regression is referred to as Weighted Logistic Regression, ClassWeighted Logistic Regression or CostSensitive Logistic Regression.
The weightings are sometimes referred to as importance weightings.
Although straightforward to implement, the challenge of weighted logistic regression is the choice of the weighting to use for each class.
Weighted Logistic Regression with ScikitLearn
The scikitlearn Python machine learning library provides an implementation of logistic regression that supports class weighting.
The LogisticRegression class provides the class_weight argument that can be specified as a model hyperparameter. The class_weight is a dictionary that defines each class label (e.g. 0 and 1) and the weighting to apply in the calculation of the negative log likelihood when fitting the model.
For example, a 1 to 1 weighting for each class 0 and 1 can be defined as follows:

... # define model weights = 0:1.0, 1:1.0 model = LogisticRegression(solver=‘lbfgs’, class_weight=weights) 
The class weighing can be defined multiple ways; for example:
 Domain expertise, determined by talking to subject matter experts.
 Tuning, determined by a hyperparameter search such as a grid search.
 Heuristic, specified using a general best practice.
A best practice for using the class weighting is to use the inverse of the class distribution present in the training dataset.
For example, the class distribution of the test dataset is a 1:100 ratio for the minority class to the majority class. The inversion of this ratio could be used with 1 for the majority class and 100 for the minority class; for example:

... # define model weights = 0:1.0, 1:100.0 model = LogisticRegression(solver=‘lbfgs’, class_weight=weights) 
We might also define the same ratio using fractions and achieve the same result; for example:

... # define model weights = 0:0.01, 1:1.0 model = LogisticRegression(solver=‘lbfgs’, class_weight=weights) 
We can evaluate the logistic regression algorithm with a class weighting using the same evaluation procedure defined in the previous section.
We would expect that the classweighted version of logistic regression to perform better than the standard version of logistic regression without any class weighting.
The complete example is listed below.
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# weighted logistic regression model on an imbalanced classification dataset from numpy import mean from sklearn.datasets import make_classification from sklearn.model_selection import cross_val_score from sklearn.model_selection import RepeatedStratifiedKFold from sklearn.linear_model import LogisticRegression # generate dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # define model weights = 0:0.01, 1:1.0 model = LogisticRegression(solver=‘lbfgs’, class_weight=weights) # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # evaluate model scores = cross_val_score(model, X, y, scoring=‘roc_auc’, cv=cv, n_jobs=–1) # summarize performance print(‘Mean ROC AUC: %.3f’ % mean(scores)) 
Running the example prepares the synthetic imbalanced classification dataset, then evaluates the classweighted version of logistic regression using repeated crossvalidation.
The mean ROC AUC score is reported, in this case showing a better score than the unweighted version of logistic regression, 0.989 as compared to 0.985.
The scikitlearn library provides an implementation of the best practice heuristic for the class weighting.
It is implemented via the compute_class_weight() function and is calculated as:
 n_samples / (n_classes * n_samples_with_class)
We can test this calculation manually on our dataset. For example, we have 10,000 examples in the dataset, 9990 in class 0, and 100 in class 1.
The weighting for class 0 is calculated as:
 weighting = n_samples / (n_classes * n_samples_with_class)
 weighting = 10000 / (2 * 9990)
 weighting = 10000 / 19800
 weighting = 0.05
The weighting for class 1 is calculated as:
 weighting = n_samples / (n_classes * n_samples_with_class)
 weighting = 10000 / (2 * 100)
 weighting = 10000 / 200
 weighting = 50
We can confirm these calculations by calling the compute_class_weight() function and specifying the class_weight as “balanced.” For example:

# calculate heuristic class weighting from sklearn.utils.class_weight import compute_class_weight from sklearn.datasets import make_classification # generate 2 class dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # calculate class weighting weighting = compute_class_weight(‘balanced’, [0,1], y) print(weighting) 
Running the example, we can see that we can achieve a weighting of about 0.5 for class 0 and a weighting of 50 for class 1.
These values match our manual calculation.
The values also match our heuristic calculation above for inverting the ratio of the class distribution in the training dataset; for example:
We can use the default class balance directly with the LogisticRegression class by setting the class_weight argument to ‘balanced.’ For example:

... # define model model = LogisticRegression(solver=‘lbfgs’, class_weight=‘balanced’) 
The complete example is listed below.
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# weighted logistic regression for class imbalance with heuristic weights from numpy import mean from sklearn.datasets import make_classification from sklearn.model_selection import cross_val_score from sklearn.model_selection import RepeatedStratifiedKFold from sklearn.linear_model import LogisticRegression # generate dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # define model model = LogisticRegression(solver=‘lbfgs’, class_weight=‘balanced’) # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # evaluate model scores = cross_val_score(model, X, y, scoring=‘roc_auc’, cv=cv, n_jobs=–1) # summarize performance print(‘Mean ROC AUC: %.3f’ % mean(scores)) 
Running the example gives the same mean ROC AUC as we achieved by specifying the inverse class ratio manually.
Grid Search Weighted Logistic Regression
Using a class weighting that is the inverse ratio of the training data is just a heuristic.
It is possible that better performance can be achieved with a different class weighting, and this too will depend on the choice of performance metric used to evaluate the model.
In this section, we will grid search a range of different class weightings for weighted logistic regression and discover which results in the best ROC AUC score.
We will try the following weightings for class 0 and 1:
 0:100,1:1
 0:10,1:1
 0:1,1:1
 0:1,1:10
 0:1,1:100
These can be defined as grid search parameters for the GridSearchCV class as follows:

... # define grid balance = [0:100,1:1, 0:10,1:1, 0:1,1:1, 0:1,1:10, 0:1,1:100] param_grid = dict(class_weight=balance) 
We can perform the grid search on these parameters using repeated crossvalidation and estimate model performance using ROC AUC:

... # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # define grid search grid = GridSearchCV(estimator=model, param_grid=param_grid, n_jobs=–1, cv=cv, scoring=‘roc_auc’) 
Once executed, we can summarize the best configuration as well as all of the results as follows:

... # report the best configuration print(“Best: %f using %s” % (grid_result.best_score_, grid_result.best_params_)) # report all configurations means = grid_result.cv_results_[‘mean_test_score’] stds = grid_result.cv_results_[‘std_test_score’] params = grid_result.cv_results_[‘params’] for mean, stdev, param in zip(means, stds, params): print(“%f (%f) with: %r” % (mean, stdev, param)) 
Tying this together, the example below grid searches five different class weights for logistic regression on the imbalanced dataset.
We might expect that the heuristic class weighing is the best performing configuration.
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# grid search class weights with logistic regression for imbalance classification from numpy import mean from sklearn.datasets import make_classification from sklearn.model_selection import GridSearchCV from sklearn.model_selection import RepeatedStratifiedKFold from sklearn.linear_model import LogisticRegression # generate dataset X, y = make_classification(n_samples=10000, n_features=2, n_redundant=0, n_clusters_per_class=1, weights=[0.99], flip_y=0, random_state=2) # define model model = LogisticRegression(solver=‘lbfgs’) # define grid balance = [0:100,1:1, 0:10,1:1, 0:1,1:1, 0:1,1:10, 0:1,1:100] param_grid = dict(class_weight=balance) # define evaluation procedure cv = RepeatedStratifiedKFold(n_splits=10, n_repeats=3, random_state=1) # define grid search grid = GridSearchCV(estimator=model, param_grid=param_grid, n_jobs=–1, cv=cv, scoring=‘roc_auc’) # execute the grid search grid_result = grid.fit(X, y) # report the best configuration print(“Best: %f using %s” % (grid_result.best_score_, grid_result.best_params_)) # report all configurations means = grid_result.cv_results_[‘mean_test_score’] stds = grid_result.cv_results_[‘std_test_score’] params = grid_result.cv_results_[‘params’] for mean, stdev, param in zip(means, stds, params): print(“%f (%f) with: %r” % (mean, stdev, param)) 
Running the example evaluates each class weighting using repeated kfold crossvalidation and reports the best configuration and the associated mean ROC AUC score.
In this case, we can see that the 1:100 majority to minority class weighting achieved the best mean ROC score. This matches the configuration for the general heuristic.
It might be interesting to explore even more severe class weightings to see their effect on the mean ROC AUC score.

Best: 0.989077 using ‘class_weight’: 0: 1, 1: 100 0.982498 (0.016722) with: ‘class_weight’: 0: 100, 1: 1 0.983623 (0.015760) with: ‘class_weight’: 0: 10, 1: 1 0.985387 (0.013890) with: ‘class_weight’: 0: 1, 1: 1 0.988044 (0.010384) with: ‘class_weight’: 0: 1, 1: 10 0.989077 (0.006865) with: ‘class_weight’: 0: 1, 1: 100 
Further Reading
This section provides more resources on the topic if you are looking to go deeper.
Papers
Books
APIs
Summary
In this tutorial, you discovered costsensitive logistic regression for imbalanced classification.
Specifically, you learned:
 How standard logistic regression does not support imbalanced classification.
 How logistic regression can be modified to weight model error by class weight when fitting the coefficients.
 How to configure class weight for logistic regression and how to grid search different class weight configurations.
Do you have any questions?
Ask your questions in the comments below and I will do my best to answer.