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284 lines
9.5 KiB
ReStructuredText
===================================
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Tutorial: Extractive Summarization
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===================================
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This tutorial will go through the implementation of several extractive
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summarization models with spaCy.
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An *extractive* summarization system is a filter over the original document/s:
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most of the text is removed, and the remaining text is formatted as a summary.
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In contrast, an *abstractive* summarization system generates new text.
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Application Context
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-------------------
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Extractive summarization systems need an application context. We can't ask how
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to design the system without some concept of what sort of summary will be
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useful for a given application. (Contrast with speech recognition, where
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a notion of "correct" is much less application-sensitive.)
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For this, I've adopted the application context that `Flipboard`_ discuss in a
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recent blog post: they want to display lead-text to readers on mobile devices,
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so that readers can easily choose interesting links.
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I've chosen this application context for two reasons. First, `Flipboard`_ say
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they're putting something like this into production. Second, there's a ready
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source of evaluation data. We can look at the lead-text that human editors
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have chosen, and evaluate whether our automatic system chooses similar text.
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Experimental Setup
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------------------
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Instead of scraping data, I'm using articles from the New York Times Annotated
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Corpus, which is a handy dump of XML-annotated articles distributed by the LDC.
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The annotations come with a field named "online lead paragraph". Our
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summarization systems will be evaluated on their Rouge-1 overlap with this
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field.
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Further details of the experimental setup can be found in the appendices.
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.. _newyorktimes.com: http://newyorktimes.com
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.. _Flipboard: http://engineering.flipboard.com/2014/10/summarization/
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.. _vector-space model: https://en.wikipedia.org/wiki/Vector_space_model
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.. _LexRank algorithm: https://www.cs.cmu.edu/afs/cs/project/jair/pub/volume22/erkan04a-html/erkan04a.html
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.. _PageRank: https://en.wikipedia.org/wiki/PageRank
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Summarizer API
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--------------
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Each summarization model will have the following API:
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.. py:func:`summarize(nlp: spacy.en.English, headline: unicode, paragraphs: List[unicode],
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target_length: int) --> summary: unicode
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We receive the headline and a list of paragraphs, and a target length. We have
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to produce a block of text where len(text) < target_length. We want summaries
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that users will click-on, and not bounce back out of. Long-term, we want
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summaries that would keep people using the app.
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Baselines: Truncate
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-------------------
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.. code:: python
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def truncate_chars(nlp, headline, paragraphs, target_length):
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text = ' '.join(paragraphs)
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return text[:target_length - 3] + '...'
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def truncate_words(nlp, headline, paragraphs, target_length):
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text = ' '.join(paragraphs)
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tokens = text.split()
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summary = []
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n_words = 0
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n_chars = 0
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while n_chars < target_length - 3:
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n_chars += len(tokens[n_words])
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n_chars += 1 # Space
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n_words += 1
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return ' '.join(tokens[:n_words]) + '...'
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def truncate_sentences(nlp, headline, paragraphs, target_length):
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sentences = []
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summary = ''
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for para in paragraphs:
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tokens = nlp(para)
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for sentence in tokens.sentences():
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if len(summary) + len(sentence) >= target_length:
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return summary
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summary += str(sentence)
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return summary
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I'd be surprised if Flipboard never had something like this in production. Details
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like lead-text take a while to float up the priority list. This strategy also has
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the advantage of transparency: it's obvious to users how the decision is being
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made, so nobody is likely to complain about the feature if it works this way.
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Instead of cutting off the text mid-word, we can tokenize the text, and
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+----------------+-----------+
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| System | Rouge-1 R |
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+----------------+-----------+
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| Truncate chars | 69.3 |
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+----------------+-----------+
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| Truncate words | 69.8 |
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+----------------+-----------+
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| Truncate sents | 48.5 |
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+----------------+-----------+
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Sentence Vectors
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----------------
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A simple bag-of-words model can be created using the `count_by` method, which
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produces a dictionary of frequencies, keyed by string IDs:
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.. code:: python
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>>> from spacy.en import English
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>>> from spacy.en.attrs import SIC
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>>> nlp = English()
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>>> tokens = nlp(u'a a a. b b b b.')
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>>> tokens.count_by(SIC)
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{41L: 4, 11L: 3, 5L: 2}
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>>> [s.count_by(SIC) for s in tokens.sentences()]
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[{11L: 3, 5L: 1}, {41L: 4, 5L: 1}]
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Similar functionality is provided by `scikit-learn`_, but with a different
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style of API design. With spaCy, functions generally have more limited
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responsibility. The advantage of this is that spaCy's APIs are much simpler,
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and it's often easier to compose functions in a more flexible way.
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One particularly powerful feature of spaCy is its support for
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`word embeddings`_ --- the dense vectors introduced by deep learning models, and
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now commonly produced by `word2vec`_ and related systems.
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Once a set of word embeddings has been installed, the vectors are available
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from any token:
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>>> from spacy.en import English
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>>> from spacy.en.attrs import SIC
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>>> from scipy.spatial.distance import cosine
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>>> nlp = English()
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>>> tokens = nlp(u'Apple banana Batman hero')
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>>> cosine(tokens[0].vec, tokens[1].vec)
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.. _word embeddings: https://colah.github.io/posts/2014-07-NLP-RNNs-Representations/
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.. _word2vec: https://code.google.com/p/word2vec/
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.. code:: python
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def main(db_loc, output_dir, feat_type="tfidf"):
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nlp = spacy.en.English()
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# Read stop list and make TF-IDF weights --- data needed for the
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# feature extraction.
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with open(stops_loc) as file_:
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stop_words = set(nlp.vocab.strings[word.strip()] for word in file_)
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idf_weights = get_idf_weights(nlp, iter_docs(db_loc))
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if feat_type == 'tfidf':
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feature_extractor = tfidf_extractor(stop_words, idf_weights)
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elif feat_type == 'vec':
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feature_extractor = vec_extractor(stop_words, idf_weights)
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for i, text in enumerate(iter_docs(db_loc)):
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tokens = nlp(body)
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sentences = tokens.sentences()
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summary = summarize(sentences, feature_extractor)
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write_output(summary, output_dir, i)
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.. _scikit-learn: http://scikit-learn.org/stable/modules/classes.html#module-sklearn.feature_extraction.text
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The LexRank Algorithm
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----------------------
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LexRank is described as a graph-based algorithm, derived from `Google's PageRank`_.
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The nodes are sentences, and the edges are the similarities between one
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sentence and another. The "graph" is fully-connected, and its edges are
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undirected --- so, it's natural to represent this as a matrix:
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.. code:: python
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from scipy.spatial.distance import cosine
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import numpy
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def lexrank(sent_vectors):
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n = len(sent_vectors)
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# Build the cosine similarity matrix
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matrix = numpy.ndarray(shape=(n, n))
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for i in range(n):
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for j in range(n):
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matrix[i, j] = cosine(sent_vectors[i], sent_vectors[j])
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# Normalize
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for i in range(n):
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matrix[i] /= sum(matrix[i])
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return _pagerank(matrix)
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The rows are normalized (i.e. rows sum to 1), allowing the PageRank algorithm
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to be applied. Unfortunately the PageRank implementation is rather opaque ---
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it's easier to just read the Wikipedia page:
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.. code:: python
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def _pagerank(matrix, d=0.85):
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# This is admittedly opaque --- just read the Wikipedia page.
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n = len(matrix)
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rank = numpy.ones(shape=(n,)) / n
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new_rank = numpy.zeros(shape=(n,))
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while not _has_converged(rank, new_rank):
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rank, new_rank = new_rank, rank
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for i in range(n):
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new_rank[i] = ((1.0 - d) / n) + (d * sum(rank * matrix[i]))
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return rank
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def _has_converged(x, y, epsilon=0.0001):
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return all(abs(x[i] - y[i]) < epsilon for i in range(n))
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Initial Processing
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------------------
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Feature Extraction
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------------------
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.. code:: python
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def sentence_vectors(sentence, idf_weights):
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tf_idf = {}
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for term, freq in sent.count_by(LEMMA).items():
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tf_idf[term] = freq * idf_weights[term]
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vectors.append(tf_idf)
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return vectors
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The LexRank paper models each sentence as a bag-of-words
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This is simple and fairly standard, but often gives
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underwhelming results. My idea is to instead calculate vectors from
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`word-embeddings`_, which have been one of the exciting outcomes of the recent
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work on deep-learning. I had a quick look at the literature, and found
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a `recent workshop paper`_ that suggested the idea was plausible.
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Taking the feature representation and similarity function as parameters, the
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LexRank function looks like this:
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Given a list of N sentences, a function that maps a sentence to a feature
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vector, and a function that computes a similarity measure of two feature
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vectors, this produces a vector of N floats, which indicate how well each
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sentence represents the document as a whole.
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.. _Rouge: https://en.wikipedia.org/wiki/ROUGE_%28metric%29
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.. _word embeddings: https://colah.github.io/posts/2014-07-NLP-RNNs-Representations/
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.. _recent workshop paper: https://www.aclweb.org/anthology/W/W14/W14-1504.pdf
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Document Model
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--------------
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