The previous four sections have given a general overview of the concepts of machine learning. In this section and the ones that follow, we will be taking a closer look at several specific algorithms for supervised and unsupervised learning, starting here with naive Bayes classification.
Naive Bayes models are a group of extremely fast and simple classification algorithms that are often suitable for very high-dimensional datasets. Because they are so fast and have so few tunable parameters, they end up being very useful as a quick-anddirty baseline for a classification problem. This section will focus on an intuitive explanation of how naive Bayes classifiers work, followed by a couple examples of them in action on some datasets.
Bayesian Classification
Naive Bayes classifiers are built on Bayesian classification methods. These rely on Bayes’s theorem, which is an equation describing the relationship of conditional probabilities of statistical quantities. In Bayesian classification, we’re interested in finding the probability of a label given some observed features, which we can write as P(L|features) . Bayes’s theorem tells us how to express this in terms of quantities we can compute more directly:
All we need now is some model by which we can compute P(features|Li) for each label. Such a model is called a generative model because it specifies the hypothetical random process that generates the data. Specifying this generative model for each label is the main piece of the training of such a Bayesian classifier. The general version of such a training step is a very difficult task, but we can make it simpler through the use of some simplifying assumptions about the form of this model.
This is where the “naive” in “naive Bayes” comes in: if we make very naive assumptions about the generative model for each label, we can find a rough approximation of the generative model for each class, and then proceed with the Bayesian classification. Different types of naive Bayes classifiers rest on different naive assumptions about the data, and we will examine a few of these in the following sections. We begin with the standard imports:
- %matplotlib inline
- import numpy as np
- import matplotlib.pyplot as plt
- import seaborn as sns; sns.set()
Perhaps the easiest naive Bayes classifier to understand is Gaussian naive Bayes. In this classifier, the assumption is that data from each label is drawn from a simple Gaussian distribution. Imagine that you have the following data (Figure 5-38):
- from sklearn.datasets import make_blobs
- X, y = make_blobs(100, 2, centers=2, random_state=2, cluster_std=1.5)
- plt.scatter(X[:, 0], X[:, 1], c=y, s=50, cmap='RdBu');
Figure 5-38. Data for Gaussian naive Bayes classification
One extremely fast way to create a simple model is to assume that the data is described by a Gaussian distribution with no covariance between dimensions. We can fit this model by simply finding the mean and standard deviation of the points within each label, which is all you need to define such a distribution. The result of this naive Gaussian assumption is shown in Figure 5-39.
Figure 5-39. Visualization of the Gaussian naive Bayes model
The ellipses here represent the Gaussian generative model for each label, with larger probability toward the center of the ellipses. With this generative model in place for each class, we have a simple recipe to compute the likelihood P(features | L1) for any data point, and thus we can quickly compute the posterior ratio and determine which label is the most probable for a given point.
This procedure is implemented in Scikit-Learn’s sklearn.naive_bayes.GaussianNB estimator:
- from sklearn.naive_bayes import GaussianNB
- model = GaussianNB()
- model.fit(X, y);
- rng = np.random.RandomState(0)
- Xnew = [-6, -14] + [14, 18] * rng.rand(2000, 2)
- ynew = model.predict(Xnew)
- plt.scatter(X[:, 0], X[:, 1], c=y, s=50, cmap='RdBu')
- lim = plt.axis()
- plt.scatter(Xnew[:, 0], Xnew[:, 1], c=ynew, s=20, cmap='RdBu', alpha=0.1)
- plt.axis(lim);
Figure 5-40. Visualization of the Gaussian naive Bayes classification
We see a slightly curved boundary in the classifications—in general, the boundary in Gaussian naive Bayes is quadratic. A nice piece of this Bayesian formalism is that it naturally allows for probabilistic classification, which we can compute using the predict_proba method:
- yprob = model.predict_proba(Xnew)
- yprob[-8:].round(2)
- array([[0.89, 0.11],
- [1. , 0. ],
- [1. , 0. ],
- [1. , 0. ],
- [1. , 0. ],
- [1. , 0. ],
- [0. , 1. ],
- [0.15, 0.85]])
Multinomial Naive Bayes
The Gaussian assumption just described is by no means the only simple assumption that could be used to specify the generative distribution for each label. Another useful example is multinomial naive Bayes, where the features are assumed to be generated from a simple multinomial distribution. The multinomial distribution describes the probability of observing counts among a number of categories, and thus multinomial naive Bayes is most appropriate for features that represent counts or count rates.
The idea is precisely the same as before, except that instead of modeling the data distribution with the best-fit Gaussian, we model the data distribution with a best-fit multinomial distribution.
Example: Classifying text
the features are related to word counts or frequencies within the documents to be classified. We discussed the extraction of such features from text in “Feature Engineering” on page 375; here we will use the sparse word count features from the 20 Newsgroups corpus to show how we might classify these short documents into categories.
Let’s download the data and take a look at the target names:
- from sklearn.datasets import fetch_20newsgroups
- data = fetch_20newsgroups()
- data.target_names
- categories = ['talk.religion.misc', 'soc.religion.christian', 'sci.space', 'comp.graphics']
- train = fetch_20newsgroups(subset='train', categories=categories)
- test = fetch_20newsgroups(subset='test', categories=categories)
In order to use this data for machine learning, we need to be able to convert the content of each string into a vector of numbers. For this we will use the TF–IDF vectorizer (discussed in “Feature Engineering” on page 375), and create a pipeline that attaches it to a multinomial naive Bayes classifier:
- from sklearn.feature_extraction.text import TfidfVectorizer
- from sklearn.naive_bayes import MultinomialNB
- from sklearn.pipeline import make_pipeline
- model = make_pipeline(TfidfVectorizer(), MultinomialNB())
- model.fit(train.data, train.target)
- labels = model.predict(test.data)
- from sklearn.metrics import confusion_matrix
- mat = confusion_matrix(test.target, labels)
- sns.heatmap(mat.T, square=True, annot=True, fmt='d', cbar=False,
- xticklabels=train.target_names, yticklabels=train.target_names)
- plt.xlabel('true label')
- plt.ylabel('predicted label');
Figure 5-41. Confusion matrix for the multinomial naive Bayes text classifier
Evidently, even this very simple classifier can successfully separate space talk from computer talk, but it gets confused between talk about religion and talk about Christianity. This is perhaps an expected area of confusion! The very cool thing here is that we now have the tools to determine the category for any string, using the predict() method of this pipeline. Here’s a quick utility function that will return the prediction for a single string:
- def predict_category(s, train=train, model=model):
- pred = model.predict([s])
- return train.target_names[pred[0]]
- for s in [
- 'sending a payload to the ISS',
- 'discussing islam vs atheism',
- 'determining the screen resolution'
- ]:
- cate = predict_category(s)
- print("'{}' is predicated as cate={}".format(s, cate))
Remember that this is nothing more sophisticated than a simple probability model for the (weighted) frequency of each word in the string; nevertheless, the result is striking. Even a very naive algorithm, when used carefully and trained on a large set of high-dimensional data, can be surprisingly effective.
When to Use Naive Bayes
Because naive Bayesian classifiers make such stringent assumptions about data, they will generally not perform as well as a more complicated model. That said, they have several advantages:
These advantages mean a Naive Bayesian classifier is often a good choice as an initial baseline classification. If it performs suitably, then congratulations: you have a very fast, very interpretable classifier for your problem. If it does not perform well, then you can begin exploring more sophisticated models, with some baseline knowledge of how well they should perform.
Naive Bayes classifiers tend to perform especially well in one of the following situations:
The last two points seem distinct, but they actually are related: as the dimension of a dataset grows, it is much less likely for any two points to be found close together (after all, they must be close in every single dimension to be close overall). This means that clusters in high dimensions tend to be more separated, on average, than clusters in low dimensions, assuming the new dimensions actually add information. For this reason, simplistic classifiers like naive Bayes tend to work as well or better than more complicated classifiers as the dimensionality grows: once you have enough data, even a simple model can be very powerful.
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