spaCy/website/usage/_vectors-similarity/_in-context.jade

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2017-10-03 12:26:20 +00:00
//- 💫 DOCS > USAGE > VECTORS & SIMILARITY > IN CONTEXT
p
| Aside from spaCy's built-in word vectors, which were trained on a lot of
| text with a wide vocabulary, the parsing, tagging and NER models also
| rely on vector representations of the #[strong meanings of words in context].
| As the first component of the
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| #[+a("/usage/processing-pipelines") processing pipeline], the
| tensorizer encodes a document's internal meaning representations as an
| array of floats, also called a tensor. This allows spaCy to make a
| reasonable guess at a word's meaning, based on its surrounding words.
| Even if a word hasn't been seen before, spaCy will know #[em something]
| about it. Because spaCy uses a 4-layer convolutional network, the
| tensors are sensitive to up to #[strong four words on either side] of a
| word.
p
| For example, here are three sentences containing the out-of-vocabulary
| word "labrador" in different contexts.
+code.
doc1 = nlp(u"The labrador barked.")
doc2 = nlp(u"The labrador swam.")
doc3 = nlp(u"the labrador people live in canada.")
for doc in [doc1, doc2, doc3]:
labrador = doc[1]
dog = nlp(u"dog")
print(labrador.similarity(dog))
p
| Even though the model has never seen the word "labrador", it can make a
| fairly accurate prediction of its similarity to "dog" in different
| contexts.
+table(["Context", "labrador.similarity(dog)"])
+row
+cell The #[strong labrador] barked.
+cell #[code 0.56] #[+procon("pro")]
+row
+cell The #[strong labrador] swam.
+cell #[code 0.48] #[+procon("con")]
+row
+cell the #[strong labrador] people live in canada.
+cell #[code 0.39] #[+procon("con")]
p
| The same also works for whole documents. Here, the variance of the
| similarities is lower, as all words and their order are taken into
| account. However, the context-specific similarity is often still
| reflected pretty accurately.
+code.
doc1 = nlp(u"Paris is the largest city in France.")
doc2 = nlp(u"Vilnius is the capital of Lithuania.")
doc3 = nlp(u"An emu is a large bird.")
for doc in [doc1, doc2, doc3]:
for other_doc in [doc1, doc2, doc3]:
print(doc.similarity(other_doc))
p
| Even though the sentences about Paris and Vilnius consist of different
| words and entities, they both describe the same concept and are seen as
| more similar than the sentence about emus. In this case, even a misspelled
| version of "Vilnius" would still produce very similar results.
+table
- var examples = {"Paris is the largest city in France.": [1, 0.85, 0.65], "Vilnius is the capital of Lithuania.": [0.85, 1, 0.55], "An emu is a large bird.": [0.65, 0.55, 1]}
- var counter = 0
+row
+row
+cell
for _, label in examples
+cell=label
each cells, label in examples
+row(counter ? null : "divider")
+cell=label
for cell in cells
+cell.u-text-center #[code=cell.toFixed(2)]
| #[+procon(cell < 0.7 ? "con" : cell != 1 ? "pro" : "neutral")]
- counter++
p
| Sentences that consist of the same words in different order will likely
| be seen as very similar but never identical.
+code.
docs = [nlp(u"dog bites man"), nlp(u"man bites dog"),
nlp(u"man dog bites"), nlp(u"dog man bites")]
for doc in docs:
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for other_doc in docs:
print(doc.similarity(other_doc))
p
| Interestingly, "man bites dog" and "man dog bites" are seen as slightly
| more similar than "man bites dog" and "dog bites man". This may be a
| conincidence or the result of "man" being interpreted as both sentence's
| subject.
+table
- var examples = {"dog bites man": [1, 0.9, 0.89, 0.92], "man bites dog": [0.9, 1, 0.93, 0.9], "man dog bites": [0.89, 0.93, 1, 0.92], "dog man bites": [0.92, 0.9, 0.92, 1]}
- var counter = 0
+row
+row
+cell
for _, label in examples
+cell.u-text-center=label
each cells, label in examples
+row(counter ? null : "divider")
+cell=label
for cell in cells
+cell.u-text-center #[code=cell.toFixed(2)]
| #[+procon(cell < 0.7 ? "con" : cell != 1 ? "pro" : "neutral")]
- counter++