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I am dealing with a multi-class problem (4 classes) and I am trying to solve it with scikit-learn in Python.

I saw that I have three options:

  1. I simply instantiate a classifier, then I fit with train and evaluate with test;

    classifier = sv.LinearSVC(random_state=123)
    classifier.fit(Xtrain, ytrain)
    classifier.score(Xtest, ytest)
    
  2. I "encapsulate" the instantiated classifier in a OneVsRest object, generating a new classifier that I use for train and test;

    classifier = OneVsRestClassifier(svm.LinearSVC(random_state=123))
    classifier.fit(Xtrain, ytrain)
    classifier.score(Xtest, ytest)
    
  3. I "encapsulate" the instantiated classifier in a OneVsOne object, generating a new classifier that I use for train and test.

    classifier = OneVsOneClassifier(svm.LinearSVC(random_state=123))
    classifier.fit(Xtrain, ytrain)
    classifier.score(Xtest, ytest)
    

I understand the difference between OneVsRest and OneVsOne, but I cannot understand what I am doing in the first scenario where I do not explicitly pick up any of these two options. What does scikit-learn do in that case? Does it implicitly use OneVsRest?

Any clarification on the matter would be highly appreciated.

Best, MR

Edit: Just to make things clear, I am not specifically interested in the case of SVMs. For example, what about RandomForest?

  • 2
    Please format your code – desertnaut Aug 28 '18 at 10:30
  • You're right. I did it many times and somehow the code formatting was not working, so I eventually gave up. – rusiano Aug 28 '18 at 10:51
  • Essentially explained in the scikit-learn docs: Multiclass and multilabel algorithms – desertnaut Aug 28 '18 at 12:34
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Updated answer: As clarified in the comments and edits, the question is more about the general setting of sklearn, and less about the specific case of LinearSVC which is explained below.

The main difference here is that some of the classifiers you can use have "built-in multiclass classification support", i.e. it is possible for that algorithm to discern between more than two classes by default. One example for this would for example be a Random Forest, or a Multi-Layer Perceptron (MLP) with multiple output nodes.

In these cases, having a OneVs object is not required at all, since you are already solving your task. In fact, using such a strategie might even decreaes your performance, since you are "hiding" potential correlations from the algorithm, by letting it only decide between single binary instances.

On the other hand, algorithms like SVC or LinearSVC only support binary classification. So, to extend these classes of (well-performing) algorithms, we instead have to rely on the reduction to a binary classification task, from our initial multiclass classification task.

As far as I am aware of, the most complete overview can be found here: If you scroll down a little bit, you can see which one of the algorithms is inherently multiclass, or uses either one of the strategies by default.
Note that all of the listed algorithms under OVO actually now employ a OVR strategy by default! This seems to be slightly outdated information in that regard.

Initial answer:

This is a question that can easily be answered by looking at the relevant scikit-learn documentation.
Generally, the expectation on Stackoverflow is that you have at least done some form of research on your own, so please consider looking into existing documentation first.

multi_class : string, ‘ovr’ or ‘crammer_singer’ (default=’ovr’)

Determines the multi-class strategy if y contains more than two classes. "ovr" trains n_classes one-vs-rest classifiers, while "crammer_singer" optimizes a joint objective over all classes. While crammer_singer is interesting from a theoretical perspective as it is consistent, it is seldom used in practice as it rarely leads to better accuracy and is more expensive to compute. If "crammer_singer" is chosen, the options loss, penalty and dual will be ignored.

So, clearly, it uses one-vs-rest.

The same holds by the way for the "regular" SVC.

  • 2
    Let me thank you for your quick reply, but let me also tell you I do not like this attitude. I did prior research and I could not find the information. Indeed, although I put svm in the example I was working with RandomForest and I do not see that parameter for RF. What's the answer then? – rusiano Aug 28 '18 at 10:50
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    @rusiano the answer is correct as far as your original question is concerned. Changing the question after an answer has been provided is far from good practice; please accept the answer and open a different question if you still have issues. – desertnaut Aug 28 '18 at 10:58
  • I never said I am interested in knowing explicitly about SVM. The question still remains, it's just your answer that is partial. – rusiano Aug 28 '18 at 11:04
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    @rusiano 1) "but I cannot understand what I am doing in the first scenario [...] What does scikit-learn do in that case?" - your first scenario explicitly involves SVM 2) please, try to argue in a productive way (we all do mistakes, the point is not to pointlessly defend them), and remember that people here are voluntarily trying to help 3) consider me a third-party observer (the answer is not mine)... – desertnaut Aug 28 '18 at 11:26
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    To chime in here: I understood it with the SVM case as well, so thanks for clearing that up. I'm currently looking into how I can best explain the concept of OVO/OVR in this (more general) context, so I'll update the answer hopefully in a little while. My harsh response with regards to the search is that it seemed to me as it was literally just looking it up for SVM; in a more general context, I consider this a more accurate and relevant question. – dennlinger Aug 28 '18 at 11:34

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