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title: Vectors and Embeddings
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menu:
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- ["What's a Word Vector?", 'whats-a-vector']
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- ['Word Vectors', 'vectors']
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- ['Other Embeddings', 'embeddings']
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- ['Using Word Vectors', 'usage']
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- ['Converting and Importing', 'converting']
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next: /usage/transformers
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---
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An old idea in linguistics is that you can "know a word by the company it
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keeps": that is, word meanings can be understood relationally, based on their
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patterns of usage. This idea inspired a branch of NLP research known as
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"distributional semantics" that has aimed to compute databases of lexical
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knowledge automatically. The [Word2vec](https://en.wikipedia.org/wiki/Word2vec)
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family of algorithms are a key milestone in this line of research. For
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simplicity, we will refer to a distributional word representation as a "word
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vector", and algorithms that computes word vectors (such as
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[GloVe](https://nlp.stanford.edu/projects/glove/),
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[FastText](https://fasttext.cc), etc.) as "Word2vec algorithms".
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Word vector tables (or "embeddings") let you find similar terms, and can improve
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the accuracy of some of your components. You can even use word vectors as a
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quick-and-dirty text-classification solution when you don't have any training data.
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Word vector tables are included in some of the spaCy [model packages](/models)
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we distribute, and you can easily create your own model packages with word
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vectors you train or download yourself. In some cases you can also add word
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vectors to an existing pipeline, although each pipeline can only have a single
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word vectors table, and a model package that already has word vectors is
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unlikely to work correctly if you replace the vectors with new ones.
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vectors you train or download yourself.
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## What's a word vector? {#whats-a-vector}
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@ -42,6 +31,17 @@ def what_is_a_word_vector(
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return vectors_table[key2row.get(word_id, default_row)]
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```
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An old idea in linguistics is that you can "know a word by the company it
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keeps": that is, word meanings can be understood relationally, based on their
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patterns of usage. This idea inspired a branch of NLP research known as
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"distributional semantics" that has aimed to compute databases of lexical
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knowledge automatically. The [Word2vec](https://en.wikipedia.org/wiki/Word2vec)
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family of algorithms are a key milestone in this line of research. For
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simplicity, we will refer to a distributional word representation as a "word
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vector", and algorithms that computes word vectors (such as
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[GloVe](https://nlp.stanford.edu/projects/glove/),
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[FastText](https://fasttext.cc), etc.) as "Word2vec algorithms".
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Word2vec algorithms try to produce vectors tables that let you estimate useful
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relationships between words using simple linear algebra operations. For
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instance, you can often find close synonyms of a word by finding the vectors
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@ -51,14 +51,15 @@ statistical models.
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### Word vectors vs. contextual language models {#vectors-vs-language-models}
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The key difference between word vectors and contextual language models such as
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ElMo, BERT and GPT-2 is that word vectors model **lexical types**, rather than
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_tokens_. If you have a list of terms with no context around them, a model like
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BERT can't really help you. BERT is designed to understand language **in
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context**, which isn't what you have. A word vectors table will be a much better
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fit for your task. However, if you do have words in context — whole sentences or
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paragraphs of running text — word vectors will only provide a very rough
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approximation of what the text is about.
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The key difference between word vectors and contextual language models such
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as [transformers](/usage/transformers)
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is that word vectors model **lexical types**, rather than
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_tokens_. If you have a list of terms with no context around them,
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a transformer model like BERT can't really help you. BERT is designed to understand
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language **in context**, which isn't what you have. A word vectors table will be
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a much better fit for your task. However, if you do have words in context — whole
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sentences or paragraphs of running text — word vectors will only provide a very
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rough approximation of what the text is about.
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Word vectors are also very computationally efficient, as they map a word to a
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vector with a single indexing operation. Word vectors are therefore useful as a
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@ -69,7 +70,7 @@ gradients to the pretrained word vectors table. The static vectors table is
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usually used in combination with a smaller table of learned task-specific
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embeddings.
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## Using word vectors directly {#vectors}
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## Using word vectors {#usage}
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spaCy stores word vector information in the
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[`Vocab.vectors`](/api/vocab#attributes) attribute, so you can access the whole
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@ -85,7 +86,141 @@ whether you've configured spaCy to use GPU memory), with dtype `float32`. The
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array is read-only so that spaCy can avoid unnecessary copy operations where
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possible. You can modify the vectors via the `Vocab` or `Vectors` table.
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### Converting word vectors for use in spaCy
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### Word vectors and similarity
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A common use-case of word vectors is to answer _similarity questions_. You can
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ask how similar a `token`, `span`, `doc` or `lexeme` is to another object using
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the `.similarity()` method. You can even check the similarity of mismatched
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types, asking how similar a whole document is to a particular word, how similar
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a span is to a document, etc. By default, the `.similarity()` method will use
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return the cosine of the `.vector` attribute of the two objects being compared.
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You can customize this behavior by setting one or more
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[user hooks](/usage/processing-pipelines#custom-components-user-hooks) for the
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types you want to customize.
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Word vector similarity is a practical technique for many situations, especially
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since it's easy to use and relatively efficient to compute. However, it's
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important to maintain realistic expectations about what information it can
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provide. Words can be related to each over in many ways, so a single
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"similarity" score will always be a mix of different signals. The word vectors
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model is also not trained for your specific use-case, so you have no way of
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telling it which results are more or less useful for your purpose. These
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problems are even more accute when you go from measuring the similarity of
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single words to the similarity of spans or documents. The vector averaging
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process is insensitive to the order of the words, so `doc1.similarity(doc2)`
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will mostly be based on the overlap in lexical items between the two documents
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objects. Two documents expressing the same meaning with dissimilar wording will
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return a lower similarity score than two documents that happen to contain the
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same words while expressing different meanings.
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### Using word vectors in your models
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Many neural network models are able to use word vector tables as additional
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features, which sometimes results in significant improvements in accuracy.
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spaCy's built-in embedding layer, `spacy.MultiHashEmbed.v1`, can be configured
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to use word vector tables using the `also_use_static_vectors` flag. This
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setting is also available on the `spacy.MultiHashEmbedCNN.v1` layer, which
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builds the default token-to-vector encoding architecture.
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```
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[tagger.model.tok2vec.embed]
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@architectures = "spacy.MultiHashEmbed.v1"
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width = 128
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rows = 7000
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also_embed_subwords = true
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also_use_static_vectors = true
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```
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<Infobox title="How it works">
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The configuration system will look up the string `spacy.MultiHashEmbed.v1`
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in the `architectures` registry, and call the returned object with the
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rest of the arguments from the block. This will result in a call to the
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`spacy.ml.models.tok2vec.MultiHashEmbed` function, which will return
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a Thinc model object with the type signature `Model[List[Doc],
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List[Floats2d]]`. Because the embedding layer takes a list of `Doc` objects as
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input, it does not need to store a copy of the vectors table. The vectors will
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be retrieved from the `Doc` objects that are passed in, via the
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`doc.vocab.vectors` attribute. This part of the process is handled by the
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`spacy.ml.staticvectors.StaticVectors` layer.
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</Infobox>
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#### Creating a custom embedding layer
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The `MultiHashEmbed` layer is spaCy's recommended strategy for constructing
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initial word representations for your neural network models, but you can also
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implement your own. You can register any function to a string name, and then
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reference that function within your config (see the [training]("/usage/training")
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section for more details). To try this out, you can save the following little
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example to a new Python file:
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```
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from spacy.ml.staticvectors import StaticVectors
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from spacy.util import registry
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print("I was imported!")
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@registry.architectures("my_example.MyEmbedding.v1")
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def MyEmbedding(output_width: int) -> Model[List[Doc], List[Floats2d]]:
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print("I was called!")
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return StaticVectors(nO=output_width)
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```
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If you pass the path to your file to the `spacy train` command using the `-c`
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argument, your file will be imported, which means the decorator registering the
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function will be run. Your function is now on equal footing with any of spaCy's
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built-ins, so you can drop it in instead of any other model with the same input
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and output signature. For instance, you could use it in the tagger model as
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follows:
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```
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[tagger.model.tok2vec.embed]
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@architectures = "my_example.MyEmbedding.v1"
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output_width = 128
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```
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Now that you have a custom function wired into the network, you can start
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implementing the logic you're interested in. For example, let's say you want to
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try a relatively simple embedding strategy that makes use of static word vectors,
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but combines them via summation with a smaller table of learned embeddings.
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```python
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from thinc.api import add, chain, remap_ids, Embed
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from spacy.ml.staticvectors import StaticVectors
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@registry.architectures("my_example.MyEmbedding.v1")
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def MyCustomVectors(
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output_width: int,
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vector_width: int,
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embed_rows: int,
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key2row: Dict[int, int]
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) -> Model[List[Doc], List[Floats2d]]:
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return add(
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StaticVectors(nO=output_width),
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chain(
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FeatureExtractor(["ORTH"]),
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remap_ids(key2row),
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Embed(nO=output_width, nV=embed_rows)
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)
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)
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```
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#### When should you add word vectors to your model?
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Word vectors are not compatible with most [transformer models](/usage/transformers),
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but if you're training another type of NLP network, it's almost always worth
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adding word vectors to your model. As well as improving your final accuracy,
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word vectors often make experiments more consistent, as the accuracy you
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reach will be less sensitive to how the network is randomly initialized. High
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variance due to random chance can slow down your progress significantly, as you
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need to run many experiments to filter the signal from the noise.
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Word vector features need to be enabled prior to training, and the same word vectors
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table will need to be available at runtime as well. You cannot add word vector
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features once the model has already been trained, and you usually cannot
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replace one word vectors table with another without causing a significant loss
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of performance.
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## Converting word vectors for use in spaCy {#converting}
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Custom word vectors can be trained using a number of open-source libraries, such
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as [Gensim](https://radimrehurek.com/gensim), [Fast Text](https://fasttext.cc),
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### Adding vectors {#adding-vectors}
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You can also add word vectors individually, using the method `vocab.set_vector`.
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This is often the easiest approach if you have vectors in an arbitrary format,
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as you can read in the vectors with your own logic, and just set them with
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a simple loop. This method is likely to be slower than approaches that work
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with the whole vectors table at once, but it's a great approach for once-off
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conversions before you save out your model to disk.
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```python
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### Adding vectors
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from spacy.vocab import Vocab
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for word, vector in vector_data.items():
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vocab.set_vector(word, vector)
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```
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### Using custom similarity methods {#custom-similarity}
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By default, [`Token.vector`](/api/token#vector) returns the vector for its
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underlying [`Lexeme`](/api/lexeme), while [`Doc.vector`](/api/doc#vector) and
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[`Span.vector`](/api/span#vector) return an average of the vectors of their
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tokens. You can customize these behaviors by modifying the `doc.user_hooks`,
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`doc.user_span_hooks` and `doc.user_token_hooks` dictionaries.
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<Infobox title="Custom user hooks" emoji="📖">
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For more details on **adding hooks** and **overwriting** the built-in `Doc`,
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`Span` and `Token` methods, see the usage guide on
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[user hooks](/usage/processing-pipelines#custom-components-user-hooks).
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</Infobox>
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<!-- TODO:
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### Storing vectors on a GPU {#gpu}
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-->
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## Other embeddings {#embeddings}
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<!-- TODO: something about other embeddings -->
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