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175 lines
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175 lines
7.0 KiB
Plaintext
include ../../_includes/_mixins
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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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+h(2, "improving-accuracy") Improving accuracy on existing entity types
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p
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| To update the model, you first need to create an instance of
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| #[+api("goldparse") #[code spacy.gold.GoldParse]], with the entity labels
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| you want to learn. You will then pass this instance to the
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| #[+api("entityrecognizer#update") #[code EntityRecognizer.update()]]
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| method. For example:
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+code.
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import spacy
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from spacy.gold import GoldParse
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nlp = spacy.load('en')
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doc = nlp.make_doc(u'Facebook released React in 2014')
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gold = GoldParse(doc, entities=['U-ORG', 'O', 'U-TECHNOLOGY', 'O', 'U-DATE'])
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nlp.entity.update(doc, gold)
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p
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| You'll usually need to provide many examples to meaningfully improve the
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| system — a few hundred is a good start, although more is better. You
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| should avoid iterating over the same few examples multiple times, or the
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| model is likely to "forget" how to annotate other examples. If you
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| iterate over the same few examples, you're effectively changing the loss
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| function. The optimizer will find a way to minimize the loss on your
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| examples, without regard for the consequences on the examples it's no
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| longer paying attention to.
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p
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| One way to avoid this "catastrophic forgetting" problem is to "remind"
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| the model of other examples by augmenting your annotations with sentences
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| annotated with entities automatically recognised by the original model.
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| Ultimately, this is an empirical process: you'll need to
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| #[strong experiment on your own data] to find a solution that works best
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| for you.
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+h(2, "adding") Adding a new entity type
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p
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| You can add new entity types to an existing model. Let's say we want to
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| recognise the category #[code TECHNOLOGY]. The new category will include
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| programming languages, frameworks and platforms. First, we need to
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| register the new entity type:
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+code.
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nlp.entity.add_label('TECHNOLOGY')
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p
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| Next, iterate over your examples, calling #[code entity.update()]. As
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| above, we want to avoid iterating over only a small number of sentences.
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| A useful compromise is to run the model over a number of plain-text
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| sentences, and pass the entities to #[code GoldParse], as "true"
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| annotations. This encourages the optimizer to find a solution that
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| predicts the new category with minimal difference from the previous
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| output.
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+h(2, "saving-loading") Saving and loading
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p
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| After training our model, you'll usually want to save its state, and load
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| it back later. You can do this with the #[code Language.save_to_directory()]
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| method:
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+code.
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nlp.save_to_directory('/home/me/data/en_technology')
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p
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| To make the model more convenient to deploy, we recommend wrapping it as
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| a Python package, so that you can install it via pip and load it as a
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| module. spaCy comes with a handy #[+api("cli#package") #[code package]]
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| CLI command to create all required files and directories.
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+code(false, "bash").
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python -m spacy package /home/me/data/en_technology /home/me/my_models
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p
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| To build the package and create a #[code .tar.gz] archive, run
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| #[code python setup.py sdist] from within its directory.
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+infobox("Saving and loading models")
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| For more information and a detailed guide on how to package your model,
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| see the documentation on
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| #[+a("/docs/usage/saving-loading") saving and loading models].
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p
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| After you've generated and installed the package, you'll be able to
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| load the model as follows:
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+code.
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import en_technology
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nlp = en_technology.load()
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+h(2, "example") Example: Adding and training an #[code ANIMAL] entity
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p
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| This script shows how to add a new entity type to an existing pre-trained
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| NER model. To keep the example short and simple, only four sentences are
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| provided as examples. In practice, you'll need many more —
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| #[strong a few hundred] would be a good start. You will also likely need
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| to mix in #[strong examples of other entity types], which might be
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| obtained by running the entity recognizer over unlabelled sentences, and
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| adding their annotations to the training set.
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p
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| For the full, runnable script of this example, see
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| #[+src(gh("spacy", "examples/training/train_new_entity_type.py")) train_new_entity_type.py].
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+code("Training the entity recognizer").
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import spacy
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from spacy.pipeline import EntityRecognizer
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from spacy.gold import GoldParse
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from spacy.tagger import Tagger
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import random
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model_name = 'en'
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entity_label = 'ANIMAL'
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output_directory = '/path/to/model'
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train_data = [
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("Horses are too tall and they pretend to care about your feelings",
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[(0, 6, 'ANIMAL')]),
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("horses are too tall and they pretend to care about your feelings",
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[(0, 6, 'ANIMAL')]),
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("horses pretend to care about your feelings",
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[(0, 6, 'ANIMAL')]),
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("they pretend to care about your feelings, those horses",
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[(48, 54, 'ANIMAL')])
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]
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nlp = spacy.load(model_name)
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nlp.entity.add_label(entity_label)
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ner = train_ner(nlp, train_data, output_directory)
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def train_ner(nlp, train_data, output_dir):
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# Add new words to vocab
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for raw_text, _ in train_data:
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doc = nlp.make_doc(raw_text)
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for word in doc:
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_ = nlp.vocab[word.orth]
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for itn in range(20):
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random.shuffle(train_data)
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for raw_text, entity_offsets in train_data:
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gold = GoldParse(doc, entities=entity_offsets)
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doc = nlp.make_doc(raw_text)
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nlp.tagger(doc)
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loss = nlp.entity.update(doc, gold)
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nlp.end_training()
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nlp.save_to_directory(output_dir)
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p
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+button(gh("spaCy", "examples/training/train_new_entity_type.py"), false, "secondary") Full example
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p
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| The actual training is performed by looping over the examples, and
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| calling #[code nlp.entity.update()]. The #[code update()] method steps
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| through the words of the input. At each word, it makes a prediction. It
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| then consults the annotations provided on the #[code GoldParse] instance,
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| to see whether it was right. If it was wrong, it adjusts its weights so
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| that the correct action will score higher next time.
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p
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| After training your model, you can
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| #[+a("/docs/usage/saving-loading") save it to a directory]. We recommend wrapping
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| models as Python packages, for ease of deployment.
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