So I have two methods of classification, Discriminant analysis diaglinear classification (naive bayes) and the pure Naive Bayes classifier implemented in matlab, there are 23 classes in the entire dataset. The first method discriminant analysis:
%% Classify Clusters using Naive Bayes Classifier and classify training_data = Testdata; target_class = TestDataLabels; [class, err] = classify(UnseenTestdata, training_data, target_class,'diaglinear') cmat1 = confusionmat(UnseenTestDataLabels, class); acc1 = 100*sum(diag(cmat1))./sum(cmat1(:)); fprintf('Classifier1:\naccuracy = %.2f%%\n', acc1); fprintf('Confusion Matrix:\n'), disp(cmat1)
Yields an accuracy from the confusion matrix of 81.49% with an error rate (
err) of 0.5040 (not sure how to interpret that).
The second method Naive Bayes classifier:
%% Classify Clusters using Naive Bayes Classifier training_data = Testdata; target_class = TestDataLabels; %# train model nb = NaiveBayes.fit(training_data, target_class, 'Distribution', 'mn'); %# prediction class1 = nb.predict(UnseenTestdata); %# performance cmat1 = confusionmat(UnseenTestDataLabels, class1); acc1 = 100*sum(diag(cmat1))./sum(cmat1(:)); fprintf('Classifier1:\naccuracy = %.2f%%\n', acc1); fprintf('Confusion Matrix:\n'), disp(cmat1)
Yields an accuracy of 81.89%.
I have only did one round of cross validation, im new at matlab and supervised/unsupervised algorithms so I did the cross validation myself I just basically take 10% of the data and keeps it aside for testing purposes, as it is a random set each time I could go through it several times and take the average accuracy but the results will do for explanation purposes.
So to my problem question.
In my literature review of current methods a lot of researchers are finding that a single classification algorithm mixed with a clustering alogorithm are yeilding better accuracy results. They do this by finding the optimal number of clusters for their data and using the partioned clusters (which should be more alike than not) run each individual cluster through a classification algorithm. A process where you can use the best parts of an unsupervised algorithm in conjunction with a supervised classification algorithm.
Now im using a dataset that has been used numerous times in literature and im attempting a not so disimilar approach to others in my quest.
I first use the simple K-Means clustering which surprisingly has a good capability to cluster my data. The output looks like so:
Looking at each cluster (K1, K2...K12) class labels:
%% output the class labels of each cluster K1 = UnseenTestDataLabels(indX(clustIDX==1),:)
I find that predominatly each cluster has one class label in 9 clusters while 3 clusters contain multiple class labels. Showing that K-means has a good fit to the data.
The problem however is once I have each cluster data (cluster1, cluster2...cluster12):
%% output the real data of each cluster cluster1 = UnseenTestdata(clustIDX==1,:)
And I put each cluster through the naive bayes or discriminant analysis like so:
class1 = classify(cluster1, training_data, target_class, 'diaglinear'); class2 = classify(cluster2, training_data, target_class, 'diaglinear'); class3 = classify(cluster3, training_data, target_class, 'diaglinear'); class4 = classify(cluster4, training_data, target_class, 'diaglinear'); class5 = classify(cluster5, training_data, target_class, 'diaglinear'); class6 = classify(cluster6, training_data, target_class, 'diaglinear'); class7 = classify(cluster7, training_data, target_class, 'diaglinear'); class8 = classify(cluster8, training_data, target_class, 'diaglinear'); class9 = classify(cluster9, training_data, target_class, 'diaglinear'); class10 = classify(cluster10, training_data, target_class, 'diaglinear'); class11 = classify(cluster11, training_data, target_class, 'diaglinear'); class12 = classify(cluster12, training_data, target_class, 'diaglinear');
The accuracy becomes horrifying, 50% of the clusters are classifyed with 0% accuracy, each classified cluster (acc1, acc2,...acc12) has its own corresponding confusion matrix you can see the accuracy of each cluster here:
So my problem/question is where am I going wrong, I first thought maybe I have the data/labels mixed up for the clusters, but what I posted above looks correct I cant see an issue with it.
Why is the data that is the exact same unseen 10% data used in the first experiment yielding such strange results for the same unseen clustered data? I mean it should be noted that NB is a stable classifier and shouldnt overfit easily and seeing as the training data is vast while the clusters to be classified are concurrent overfitting shouldnt happen?
As requested from comments I have included the cmat file for the first example of testing which gives an accuracy of 81.49% and an err of 0.5040:
Also requested was the a snippet of K, class and the related cmat in this example (cluster4) the accuracy is 3.03%:
Seeing as there was a large number of classes (23 in total) I decided to reduce the classes as outlined in the 1999 KDD Cup this is just applying abit of domain knowledge as some of the attacks are more alike than others and come under one umbrella term.
I then trained the classifier with 444 thousand records while holding back 10% for testing purposes.
The accuracy was worse 73.39% the error rate was also worse 0.4261
The unseendata broken down into its classes:
DoS: 39149 Probe: 405 R2L: 121 U2R: 6 normal.: 9721
The class or classified labels (outcome of discriminant analysis)
DoS: 28135 Probe: 10776 R2L: 1102 U2R: 1140 normal.: 8249
The training data is made up of:
DoS: 352452 Probe: 3717 R2L: 1006 U2R: 49 normal.: 87395
I fear if I lower the training data to have a similar percetange of malicious activity, then the classifier wont have enough predictive power to distinguish between classes, however looking at some other literature I have noticed that some researchers remove U2R as there isnt enough data for successful classifiction.
Methods I have tryed so far are one class classifiers where I train the classifier to only predict one class (not effective), classifying indivdual clusters (worse accuracy yet), reducing the class labels (2nd best) and keeping the full 23 class labels (best accuracy).