I have built a Random Forest model for predicting if a customer is doing operations regarding to fraud or not. It is a large an a quite unbalanced sample, with 3% cases of fraud, and I want to predict the minority class (fraud).

I balance the data (50% each) and build the RF. So far, I have a good model with an overall accuracy of ~80% and a +70% fraud predicted correctly. But when I try the model on unseen data (test), although the overall accuracy is good, the negative predicted value (fraud) is really low compared to the training data (13% only vs +70%).

I have tried increasing the sample size, increasing the balanced categories, tuning RF parameters, ..., but none of them have worked well, with similar results. Am I overfitting somehow? What can I do to improve fraud detection (negative predicted value) on unseen data?

Here is the code and results:


#train and test sets
model <- sample(nrow(dataset), 0.7 * nrow(dataset))
train <- dataset[model, ]
test <- dataset[-model, ]
    #Balance the data
balanced <- ovun.sample(custom21_type ~ ., data = train, method = "over",p = 0.5, seed = 1)$data


   0    1 
5813 5861

#build the RF
rf5 = randomForest(custom21_type~.,ntree = 100,data = balanced,importance = TRUE,mtry=3,keep.inbag=TRUE)

 randomForest(formula = custom21_type ~ ., data = balanced, ntree = 100,      importance = TRUE, mtry = 3, keep.inbag = TRUE) 
               Type of random forest: classification
                     Number of trees: 100
No. of variables tried at each split: 3

        OOB estimate of  error rate: 21.47%
Confusion matrix:
     0    1 class.error
0 4713 1100   0.1892310
1 1406 4455   0.2398908

#test on unseen data
predicted <- predict(rf5, newdata=test)
Confusion Matrix and Statistics

Prediction     0     1
         0 59722   559
         1 13188  1938

               Accuracy : 0.8177          
                 95% CI : (0.8149, 0.8204)
    No Information Rate : 0.9669          
    P-Value [Acc > NIR] : 1               

                  Kappa : 0.1729          
 Mcnemar's Test P-Value : <2e-16          

            Sensitivity : 0.8191          
            Specificity : 0.7761          
         Pos Pred Value : 0.9907          
         Neg Pred Value : 0.1281          
             Prevalence : 0.9669          
         Detection Rate : 0.7920          
   Detection Prevalence : 0.7994          
      Balanced Accuracy : 0.7976          

       'Positive' Class : 0     
  • Perhaps have a validation set before running on test data and train the model using only the train set? It seems you're training on both train and test set. and using only 30% to finally "test" – NelsonGon Jan 23 '19 at 11:57
  • Thank you for the comment. I have a dataset of 251.356 rows, and created a train set of 70% and another one of 30% for test. I have changed test to 50% and results remain similar. I do not understand why you say "you're training on both train and test set". Could you please be more specific? – ecp Jan 23 '19 at 12:12
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    See here on making a reproducible example that is easier to help with. You can post a sample of data that represents the issue you're having--otherwise we're just guessing – camille Jan 28 '19 at 13:08
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    "but none of them have worked well, with similar results"..what have you done regarding feature engineering? Have you tried with different models (SVM, NN,XGB..) or better ensemble learning? Have you tried rebalancing with SMOTE? Have you done something to measure feature importance? Removing not useful variables helps with the overfit problem. I suggest to start learning what all of this means. Head over to kaggle.com and find a similar problem, they have kernels where they show you with code how it's done :) – RLave Jan 29 '19 at 8:07
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    I'd start by reading here kaggle.com/mlg-ulb/creditcardfraud/kernels. But know that there simply isn't a solution that works well on two different problems, but it might get you somewhere. – RLave Jan 29 '19 at 8:13

First I notice that you are not using any cross validation. Including this will help add variation in the data used to train and will help reduce overfitting. Additionally we are going to user C.50 in place of randomForest because it is more robust and gives more penalties to type 1 errors.

One thing you may consider is actually not having a 50-50 balance split in the train data, but making it more 80-20. This is so that the underbalanced class is not over sampled. I am sure this is leading to overfitting and the failure for your model to classify novel examples as negative.


#set up you cross validation
Control <- trainControl(
summaryFunction = twoClassSummary, #displays model score not confusion matrix
classProbs = TRUE, #important for the summaryFunction
verboseIter = TRUE, #tones down output
savePredictions = TRUE, 
method = "repeatedcv", #repeated cross validation, 10 folds, 3 times
repeats = 3,
number = 10,
allowParallel = TRUE


Now I read in the comments that all your variables are categorical. This is optimal for NaiveBayes algorithms. However if you have any numerical data you will need to preprocess (scale, normalize, and NA input) as is standard procedure. We are also going to implement a grid-searching process.


model_nb <- train(
x = balanced[,-(which(colnames(balanced))%in% "custom21_type")],
y= balanced$custom21_type,
metric = "ROC",
method = "nb", 
trControl = Control,
tuneGrid = data.frame(fL=c(0,0.5,1.0), usekernel = TRUE, 

IF YOU WOULD LIKE A RF APPROACH (make sure to preprocess if data is numeric)

model_C5 <- train(
x = balanced[,-(which(colnames(balanced))%in% "custom21_type")],
y= balanced$custom21_type,
metric = "ROC",
method = "C5.0", 
trControl = Control,
tuneGrid = tuneGrid=expand.grid(.model = "tree",.trials = c(1,5,10), .winnow = F)))

Now we predict

C5_predict<-predict(model_C5, test, type = "raw")
NB_predict<-predict(model_nb, test, type = "raw")


try adjusting the cost matrix below. What this one does is penalize type two errors twice as bad as type one errors.

cost_mat <- matrix(c(0, 2, 1, 0), nrow = 2)
rownames(cost_mat) <- colnames(cost_mat) <- c("bad", "good")
cost_mod <- C5.0( x = balanced[,-(which(colnames(balanced))%in% 
y= balanced$custom21_type,
             costs = cost_mat)


predicted <- predict(rf5, newdata=test, type="prob")

will give you the actual probabilities for each prediction. The default cut-off is .5. I.e. everything above .5 will get classified as 0 and everything below as 1. So you can adjust this cutoff to help with unbalanced classes.

ifelse(predicted[,1] < .4, 1, predicted[,1])
  • C5 gives more accuracy, 94.5% overall, still not enough: 25% of positive predicted values. NB does not work, gives warnings (+50) and cannot run the confusion matrix. Error: 50: In FUN(X[[i]], ...) : Numerical 0 probability for all classes with observation 94 – ecp Jan 29 '19 at 7:38
  • Ok see edit, that might do something for you. Notice that it does not use the train objects we defined before. – Maxwell Chandler Jan 29 '19 at 19:28
  • Your proposal works, but results look more or less the same. I will take further look at the data and try other methods. – ecp Jan 30 '19 at 14:21
  • Ok. See my next edit, this should help a little bit more – Maxwell Chandler Jan 30 '19 at 17:18
  • And how can I apply it to the model? predictedrf <- predict(rf_fit, newdata=test, type="prob") RF_predict_cutoff<-ifelse(predictedrf[,1] < .4, 1, predictedrf[,1]) confusionMatrix(RF_predict_cutoff,test$custom21_type) just fails: "Error: data and reference should be factors with the same levels." – ecp Jan 31 '19 at 8:02

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