""" Title: Imbalanced classification: credit card fraud detection Author: [fchollet](https://twitter.com/fchollet) Date created: 2019/05/28 Last modified: 2020/04/17 Description: Demonstration of how to handle highly imbalanced classification problems. Accelerator: GPU """ """ ## Introduction This example looks at the [Kaggle Credit Card Fraud Detection](https://www.kaggle.com/mlg-ulb/creditcardfraud/) dataset to demonstrate how to train a classification model on data with highly imbalanced classes. """ """ ## First, vectorize the CSV data """ import csv import numpy as np # Get the real data from https://www.kaggle.com/mlg-ulb/creditcardfraud/ fname = "/Users/fchollet/Downloads/creditcard.csv" all_features = [] all_targets = [] with open(fname) as f: for i, line in enumerate(f): if i == 0: print("HEADER:", line.strip()) continue # Skip header fields = line.strip().split(",") all_features.append([float(v.replace('"', "")) for v in fields[:-1]]) all_targets.append([int(fields[-1].replace('"', ""))]) if i == 1: print("EXAMPLE FEATURES:", all_features[-1]) features = np.array(all_features, dtype="float32") targets = np.array(all_targets, dtype="uint8") print("features.shape:", features.shape) print("targets.shape:", targets.shape) """ ## Prepare a validation set """ num_val_samples = int(len(features) * 0.2) train_features = features[:-num_val_samples] train_targets = targets[:-num_val_samples] val_features = features[-num_val_samples:] val_targets = targets[-num_val_samples:] print("Number of training samples:", len(train_features)) print("Number of validation samples:", len(val_features)) """ ## Analyze class imbalance in the targets """ counts = np.bincount(train_targets[:, 0]) print( "Number of positive samples in training data: {} ({:.2f}% of total)".format( counts[1], 100 * float(counts[1]) / len(train_targets) ) ) weight_for_0 = 1.0 / counts[0] weight_for_1 = 1.0 / counts[1] """ ## Normalize the data using training set statistics """ mean = np.mean(train_features, axis=0) train_features -= mean val_features -= mean std = np.std(train_features, axis=0) train_features /= std val_features /= std """ ## Build a binary classification model """ import keras model = keras.Sequential( [ keras.Input(shape=train_features.shape[1:]), keras.layers.Dense(256, activation="relu"), keras.layers.Dense(256, activation="relu"), keras.layers.Dropout(0.3), keras.layers.Dense(256, activation="relu"), keras.layers.Dropout(0.3), keras.layers.Dense(1, activation="sigmoid"), ] ) model.summary() """ ## Train the model with `class_weight` argument """ metrics = [ keras.metrics.FalseNegatives(name="fn"), keras.metrics.FalsePositives(name="fp"), keras.metrics.TrueNegatives(name="tn"), keras.metrics.TruePositives(name="tp"), keras.metrics.Precision(name="precision"), keras.metrics.Recall(name="recall"), ] model.compile( optimizer=keras.optimizers.Adam(1e-2), loss="binary_crossentropy", metrics=metrics ) callbacks = [keras.callbacks.ModelCheckpoint("fraud_model_at_epoch_{epoch}.keras")] class_weight = {0: weight_for_0, 1: weight_for_1} model.fit( train_features, train_targets, batch_size=2048, epochs=30, verbose=2, callbacks=callbacks, validation_data=(val_features, val_targets), class_weight=class_weight, ) """ ## Conclusions At the end of training, out of 56,961 validation transactions, we are: - Correctly identifying 66 of them as fraudulent - Missing 9 fraudulent transactions - At the cost of incorrectly flagging 441 legitimate transactions In the real world, one would put an even higher weight on class 1, so as to reflect that False Negatives are more costly than False Positives. Next time your credit card gets declined in an online purchase -- this is why. """