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136 lines
5.4 KiB
Plaintext
136 lines
5.4 KiB
Plaintext
include ../../_includes/_mixins
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p
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| This workflow describes how to train new statistical models for spaCy's
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| part-of-speech tagger, named entity recognizer and dependency parser.
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| Once the model is trained, you can then
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| #[+a("/docs/usage/saving-loading") save and load] it.
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+h(2, "train-pos-tagger") Training the part-of-speech tagger
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+code.
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from spacy.vocab import Vocab
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from spacy.tagger import Tagger
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from spacy.tokens import Doc
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from spacy.gold import GoldParse
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vocab = Vocab(tag_map={'N': {'pos': 'NOUN'}, 'V': {'pos': 'VERB'}})
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tagger = Tagger(vocab)
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doc = Doc(vocab, words=['I', 'like', 'stuff'])
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gold = GoldParse(doc, tags=['N', 'V', 'N'])
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tagger.update(doc, gold)
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tagger.model.end_training()
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p
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+button(gh("spaCy", "examples/training/train_tagger.py"), false, "secondary") Full example
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+h(2, "train-entity") Training the named entity recognizer
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+code.
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from spacy.vocab import Vocab
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from spacy.pipeline import EntityRecognizer
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from spacy.tokens import Doc
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vocab = Vocab()
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entity = EntityRecognizer(vocab, entity_types=['PERSON', 'LOC'])
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doc = Doc(vocab, words=['Who', 'is', 'Shaka', 'Khan', '?'])
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entity.update(doc, ['O', 'O', 'B-PERSON', 'L-PERSON', 'O'])
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entity.model.end_training()
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p
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+button(gh("spaCy", "examples/training/train_ner.py"), false, "secondary") Full example
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+h(2, "extend-entity") Extending the named entity recognizer
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p
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| All #[+a("/docs/usage/models") spaCy models] support online learning, so
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| you can update a pre-trained model with new examples. You can even add
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| new classes to an existing model, to recognise a new entity type,
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| part-of-speech, or syntactic relation. Updating an existing model is
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| particularly useful as a "quick and dirty solution", if you have only a
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| few corrections or annotations.
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p.o-inline-list
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+button(gh("spaCy", "examples/training/train_new_entity_type.py"), true, "secondary") Full example
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+button("/docs/usage/training-ner", false, "secondary") Usage Workflow
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+h(2, "train-dependency") Training the dependency parser
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+code.
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from spacy.vocab import Vocab
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from spacy.pipeline import DependencyParser
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from spacy.tokens import Doc
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vocab = Vocab()
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parser = DependencyParser(vocab, labels=['nsubj', 'compound', 'dobj', 'punct'])
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doc = Doc(vocab, words=['Who', 'is', 'Shaka', 'Khan', '?'])
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parser.update(doc, [(1, 'nsubj'), (1, 'ROOT'), (3, 'compound'), (1, 'dobj'),
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(1, 'punct')])
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parser.model.end_training()
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p
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+button(gh("spaCy", "examples/training/train_parser.py"), false, "secondary") Full example
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+h(2, "feature-templates") Customizing the feature extraction
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p
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| spaCy currently uses linear models for the tagger, parser and entity
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| recognizer, with weights learned using the
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| #[+a("https://explosion.ai/blog/part-of-speech-pos-tagger-in-python") Averaged Perceptron algorithm].
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+aside("Linear Model Feature Scheme")
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| For a list of the available feature atoms, see the #[+a("/docs/api/features") Linear Model Feature Scheme].
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p
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| Because it's a linear model, it's important for accuracy to build
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| conjunction features out of the atomic predictors. Let's say you have
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| two atomic predictors asking, "What is the part-of-speech of the
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| previous token?", and "What is the part-of-speech of the previous
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| previous token?". These predictors will introduce a number of features,
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| e.g. #[code Prev-pos=NN], #[code Prev-pos=VBZ], etc. A conjunction
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| template introduces features such as #[code Prev-pos=NN&Prev-pos=VBZ].
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p
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| The feature extraction proceeds in two passes. In the first pass, we
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| fill an array with the values of all of the atomic predictors. In the
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| second pass, we iterate over the feature templates, and fill a small
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| temporary array with the predictors that will be combined into a
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| conjunction feature. Finally, we hash this array into a 64-bit integer,
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| using the MurmurHash algorithm. You can see this at work in the
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| #[+a(gh("thinc", "thinc/linear/features.pyx", "94dbe06fd3c8f24d86ab0f5c7984e52dbfcdc6cb")) #[code thinc.linear.features]] module.
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p
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| It's very easy to change the feature templates, to create novel
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| combinations of the existing atomic predictors. There's currently no API
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| available to add new atomic predictors, though. You'll have to create a
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| subclass of the model, and write your own #[code set_featuresC] method.
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p
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| The feature templates are passed in using the #[code features] keyword
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| argument to the constructors of the #[+api("tagger") #[code Tagger]],
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| #[+api("dependencyparser") #[code DependencyParser]] and
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| #[+api("entityrecognizer") #[code EntityRecognizer]]:
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+code.
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from spacy.vocab import Vocab
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from spacy.pipeline import Tagger
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from spacy.tagger import P2_orth, P1_orth
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from spacy.tagger import P2_cluster, P1_cluster, W_orth, N1_orth, N2_orth
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vocab = Vocab(tag_map={'N': {'pos': 'NOUN'}, 'V': {'pos': 'VERB'}})
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tagger = Tagger(vocab, features=[(P2_orth, P2_cluster), (P1_orth, P1_cluster),
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(P2_orth,), (P1_orth,), (W_orth,),
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(N1_orth,), (N2_orth,)])
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p
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| Custom feature templates can be passed to the #[code DependencyParser]
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| and #[code EntityRecognizer] as well, also using the #[code features]
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| keyword argument of the constructor.
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