# Natural Language Toolkit: Classifiers # # Copyright (C) 2001-2018 NLTK Project # Author: Edward Loper # URL: # For license information, see LICENSE.TXT """ Classes and interfaces for labeling tokens with category labels (or "class labels"). Typically, labels are represented with strings (such as ``'health'`` or ``'sports'``). Classifiers can be used to perform a wide range of classification tasks. For example, classifiers can be used... - to classify documents by topic - to classify ambiguous words by which word sense is intended - to classify acoustic signals by which phoneme they represent - to classify sentences by their author Features ======== In order to decide which category label is appropriate for a given token, classifiers examine one or more 'features' of the token. These "features" are typically chosen by hand, and indicate which aspects of the token are relevant to the classification decision. For example, a document classifier might use a separate feature for each word, recording how often that word occurred in the document. Featuresets =========== The features describing a token are encoded using a "featureset", which is a dictionary that maps from "feature names" to "feature values". Feature names are unique strings that indicate what aspect of the token is encoded by the feature. Examples include ``'prevword'``, for a feature whose value is the previous word; and ``'contains-word(library)'`` for a feature that is true when a document contains the word ``'library'``. Feature values are typically booleans, numbers, or strings, depending on which feature they describe. Featuresets are typically constructed using a "feature detector" (also known as a "feature extractor"). A feature detector is a function that takes a token (and sometimes information about its context) as its input, and returns a featureset describing that token. For example, the following feature detector converts a document (stored as a list of words) to a featureset describing the set of words included in the document: >>> # Define a feature detector function. >>> def document_features(document): ... return dict([('contains-word(%s)' % w, True) for w in document]) Feature detectors are typically applied to each token before it is fed to the classifier: >>> # Classify each Gutenberg document. >>> from nltk.corpus import gutenberg >>> for fileid in gutenberg.fileids(): # doctest: +SKIP ... doc = gutenberg.words(fileid) # doctest: +SKIP ... print fileid, classifier.classify(document_features(doc)) # doctest: +SKIP The parameters that a feature detector expects will vary, depending on the task and the needs of the feature detector. For example, a feature detector for word sense disambiguation (WSD) might take as its input a sentence, and the index of a word that should be classified, and return a featureset for that word. The following feature detector for WSD includes features describing the left and right contexts of the target word: >>> def wsd_features(sentence, index): ... featureset = {} ... for i in range(max(0, index-3), index): ... featureset['left-context(%s)' % sentence[i]] = True ... for i in range(index, max(index+3, len(sentence))): ... featureset['right-context(%s)' % sentence[i]] = True ... return featureset Training Classifiers ==================== Most classifiers are built by training them on a list of hand-labeled examples, known as the "training set". Training sets are represented as lists of ``(featuredict, label)`` tuples. """ from nltk.classify.api import ClassifierI, MultiClassifierI from nltk.classify.megam import config_megam, call_megam from nltk.classify.weka import WekaClassifier, config_weka from nltk.classify.naivebayes import NaiveBayesClassifier from nltk.classify.positivenaivebayes import PositiveNaiveBayesClassifier from nltk.classify.decisiontree import DecisionTreeClassifier from nltk.classify.rte_classify import rte_classifier, rte_features, RTEFeatureExtractor from nltk.classify.util import accuracy, apply_features, log_likelihood from nltk.classify.scikitlearn import SklearnClassifier from nltk.classify.maxent import (MaxentClassifier, BinaryMaxentFeatureEncoding, TypedMaxentFeatureEncoding, ConditionalExponentialClassifier) from nltk.classify.senna import Senna from nltk.classify.textcat import TextCat