Metadata-Version: 2.1
Name: keyphrase-vectorizers
Version: 0.0.10
Summary: Set of vectorizers that extract keyphrases with part-of-speech patterns from a collection of text documents and convert them into a document-keyphrase matrix.
Home-page: https://github.com/TimSchopf/KeyphraseVectorizers
Author: Tim Schopf
Author-email: tim.schopf@t-online.de.de
License: BSD 3-Clause "New" or "Revised" License
Classifier: Development Status :: 3 - Alpha
Classifier: Programming Language :: Python :: 3
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Developers
Classifier: Topic :: Scientific/Engineering :: Artificial Intelligence
Classifier: Topic :: Scientific/Engineering :: Information Analysis
Classifier: License :: OSI Approved :: BSD License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.7
Description-Content-Type: text/markdown
License-File: LICENSE

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KeyphraseVectorizers
===================== 

Set of vectorizers that extract keyphrases with part-of-speech patterns from a collection of text documents and convert
them into a document-keyphrase matrix. A document-keyphrase matrix is a mathematical matrix that describes the frequency
of keyphrases that occur in a collection of documents. The matrix rows indicate the text documents and columns indicate
the unique keyphrases.

The package contains wrappers of the
[sklearn.feature_extraction.text.CountVectorizer](https://scikit-learn.org/stable/modules/generated/sklearn.feature_extraction.text.CountVectorizer.html?highlight=countvectorizer#sklearn.feature_extraction.text.CountVectorizer "scikit-learn CountVectorizer")
and
[sklearn.feature_extraction.text.TfidfVectorizer](https://scikit-learn.org/stable/modules/generated/sklearn.feature_extraction.text.TfidfVectorizer.html#sklearn.feature_extraction.text.TfidfVectorizer "scikit-learn TfidfVectorizer")
classes. Instead of using n-gram tokens of a pre-defined range, these classes extract keyphrases from text documents
using part-of-speech tags to compute document-keyphrase matrices.

Corresponding medium post can be found [here](https://towardsdatascience.com/enhancing-keybert-keyword-extraction-results-with-keyphrasevectorizers-3796fa93f4db "Keyphrase Extraction with BERT Transformers and Noun Phrases").

Benefits
--------

* Extract grammatically accurate keyphases based on their part-of-speech tags.
* No need to specify n-gram ranges.
* Get document-keyphrase matrices.
* Multiple language support.
* User-defined part-of-speech patterns for keyphrase extraction possible.

<a name="toc"/></a>

Table of Contents
-----------------

<!--ts-->

1. [How does it work?](#how-does-it-work)
2. [Installation](#installation)
3. [Usage](#usage)
   1. [KeyphraseCountVectorizer](#keyphrasecountvectorizer)
      1. [English language](#english-language)
      2. [Other languages](#other-languages)
   2. [KeyphraseTfidfVectorizer](#keyphrasetfidfvectorizer)
   3. [Custom POS-tagger](#custom-pos-tagger)
   4. [Keyphrase extraction with KeyBERT](#keyphrase-extraction-with-keybert)
   5. [Topic modeling with BERTopic and KeyphraseVectorizers](#topic-modeling-with-bertopic-and-keyphrasevectorizers)

<!--te-->

<a name="#how-does-it-work"/></a>

How does it work?
-----------------

First, the document texts are annotated with [spaCy](https://spacy.io "spaCy homepage") part-of-speech tags. A list of
all possible spaCy part-of-speech tags for different languages is
linked [here](https://github.com/explosion/spaCy/blob/master/spacy/glossary.py "spaCy POS tags"). The annotation
requires passing the [spaCy pipeline](https://spacy.io/models "available spaCy pipelines") of the corresponding language
to the vectorizer with the `spacy_pipeline` parameter.

Second, words are extracted from the document texts whose part-of-speech tags match the regex pattern defined in
the `pos_pattern`
parameter. The keyphrases are a list of unique words extracted from text documents by this method.

Finally, the vectorizers calculate document-keyphrase matrices.

<a name="#installation"/></a>

Installation
------------

```
pip install keyphrase-vectorizers
```

<a name="#usage"/></a>

Usage
-----
For detailed information visit
the [API Guide](https://keyphrase-vectorizers.readthedocs.io/en/latest/index.html "Keyphrase_Vectorizers API Guide").

<a name="#keyphrasecountvectorizer"/></a>

### KeyphraseCountVectorizer

[Back to Table of Contents](#toc)

<a name="#english-language"/></a>

#### English language

```python
from keyphrase_vectorizers import KeyphraseCountVectorizer

docs = ["""Supervised learning is the machine learning task of learning a function that
         maps an input to an output based on example input-output pairs. It infers a
         function from labeled training data consisting of a set of training examples.
         In supervised learning, each example is a pair consisting of an input object
         (typically a vector) and a desired output value (also called the supervisory signal). 
         A supervised learning algorithm analyzes the training data and produces an inferred function, 
         which can be used for mapping new examples. An optimal scenario will allow for the 
         algorithm to correctly determine the class labels for unseen instances. This requires 
         the learning algorithm to generalize from the training data to unseen situations in a 
         'reasonable' way (see inductive bias).""", 
             
        """Keywords are defined as phrases that capture the main topics discussed in a document. 
        As they offer a brief yet precise summary of document content, they can be utilized for various applications. 
        In an information retrieval environment, they serve as an indication of document relevance for users, as the list 
        of keywords can quickly help to determine whether a given document is relevant to their interest. 
        As keywords reflect a document's main topics, they can be utilized to classify documents into groups 
        by measuring the overlap between the keywords assigned to them. Keywords are also used proactively 
        in information retrieval."""]
        
# Init default vectorizer.
vectorizer = KeyphraseCountVectorizer()

# Print parameters
print(vectorizer.get_params())
>>> {'binary': False, 'dtype': <class 'numpy.int64'>, 'lowercase': True, 'max_df': None, 'min_df': None, 'pos_pattern': '<J.*>*<N.*>+', 'spacy_exclude': None, 'spacy_pipeline': 'en_core_web_sm', 'stop_words': 'english', 'workers': 1}
```

By default, the vectorizer is initialized for the English language. That means, an English `spacy_pipeline` is
specified, English `stop_words` are removed, and the `pos_pattern` extracts keywords that have 0 or more adjectives,
followed by 1 or more nouns using the English spaCy part-of-speech tags.

```python
# After initializing the vectorizer, it can be fitted
# to learn the keyphrases from the text documents.
vectorizer.fit(docs)
```

```python
# After learning the keyphrases, they can be returned.
keyphrases = vectorizer.get_feature_names_out()

print(keyphrases)
>>> ['users' 'main topics' 'learning algorithm' 'overlap' 'documents' 'output'
 'keywords' 'precise summary' 'new examples' 'training data' 'input'
 'document content' 'training examples' 'unseen instances'
 'optimal scenario' 'document' 'task' 'supervised learning algorithm'
 'example' 'interest' 'function' 'example input' 'various applications'
 'unseen situations' 'phrases' 'indication' 'inductive bias'
 'supervisory signal' 'document relevance' 'information retrieval' 'set'
 'input object' 'groups' 'output value' 'list' 'learning' 'output pairs'
 'pair' 'class labels' 'supervised learning' 'machine'
 'information retrieval environment' 'algorithm' 'vector' 'way']
```

```python
# After fitting, the vectorizer can transform the documents 
# to a document-keyphrase matrix.
# Matrix rows indicate the documents and columns indicate the unique keyphrases.
# Each cell represents the count.
document_keyphrase_matrix = vectorizer.transform(docs).toarray()

print(document_keyphrase_matrix)
>>> [[0 0 2 0 0 3 0 0 1 3 3 0 1 1 1 0 1 1 2 0 3 1 0 1 0 0 1 1 0 0 1 1 0 1 0 6
  1 1 1 3 1 0 3 1 1]
 [1 2 0 1 1 0 5 1 0 0 0 1 0 0 0 5 0 0 0 1 0 0 1 0 1 1 0 0 1 2 0 0 1 0 1 0
  0 0 0 0 0 1 0 0 0]]
```

```python
# Fit and transform can also be executed in one step, 
# which is more efficient. 
document_keyphrase_matrix = vectorizer.fit_transform(docs).toarray()

print(document_keyphrase_matrix)
>>> [[0 0 2 0 0 3 0 0 1 3 3 0 1 1 1 0 1 1 2 0 3 1 0 1 0 0 1 1 0 0 1 1 0 1 0 6
  1 1 1 3 1 0 3 1 1]
 [1 2 0 1 1 0 5 1 0 0 0 1 0 0 0 5 0 0 0 1 0 0 1 0 1 1 0 0 1 2 0 0 1 0 1 0
  0 0 0 0 0 1 0 0 0]]
```

<a name="#other-languages"/></a>

#### Other languages

[Back to Table of Contents](#toc)

```python
german_docs = ["""Goethe stammte aus einer angesehenen bürgerlichen Familie. 
                Sein Großvater mütterlicherseits war als Stadtschultheiß höchster Justizbeamter der Stadt Frankfurt, 
                sein Vater Doktor der Rechte und Kaiserlicher Rat. Er und seine Schwester Cornelia erfuhren eine aufwendige 
                Ausbildung durch Hauslehrer. Dem Wunsch seines Vaters folgend, studierte Goethe in Leipzig und Straßburg 
                Rechtswissenschaft und war danach als Advokat in Wetzlar und Frankfurt tätig. 
                Gleichzeitig folgte er seiner Neigung zur Dichtkunst.""",
              
               """Friedrich Schiller wurde als zweites Kind des Offiziers, Wundarztes und Leiters der Hofgärtnerei in 
               Marbach am Neckar Johann Kaspar Schiller und dessen Ehefrau Elisabetha Dorothea Schiller, geb. Kodweiß, 
               die Tochter eines Wirtes und Bäckers war, 1759 in Marbach am Neckar geboren
               """]
# Init vectorizer for the german language
vectorizer = KeyphraseCountVectorizer(spacy_pipeline='de_core_news_sm', pos_pattern='<ADJ.*>*<N.*>+', stop_words='german')
```

The German `spacy_pipeline` is specified and German `stop_words` are removed. Because the German spaCy part-of-speech
tags differ from the English ones, the `pos_pattern` parameter is also customized. The regex pattern `<ADJ.*>*<N.*>+`
extracts keywords that have 0 or more adjectives, followed by 1 or more nouns using the German spaCy part-of-speech
tags.

<a name="#keyphrasetfidfvectorizer"/></a>

### KeyphraseTfidfVectorizer

[Back to Table of Contents](#toc)

The `KeyphraseTfidfVectorizer` has the same function calls and features as the `KeyphraseCountVectorizer`. The only
difference is, that document-keyphrase matrix cells represent tf or tf-idf values, depending on the parameter settings,
instead of counts.

```python
from keyphrase_vectorizers import KeyphraseTfidfVectorizer

docs = ["""Supervised learning is the machine learning task of learning a function that
         maps an input to an output based on example input-output pairs. It infers a
         function from labeled training data consisting of a set of training examples.
         In supervised learning, each example is a pair consisting of an input object
         (typically a vector) and a desired output value (also called the supervisory signal). 
         A supervised learning algorithm analyzes the training data and produces an inferred function, 
         which can be used for mapping new examples. An optimal scenario will allow for the 
         algorithm to correctly determine the class labels for unseen instances. This requires 
         the learning algorithm to generalize from the training data to unseen situations in a 
         'reasonable' way (see inductive bias).""", 
             
        """Keywords are defined as phrases that capture the main topics discussed in a document. 
        As they offer a brief yet precise summary of document content, they can be utilized for various applications. 
        In an information retrieval environment, they serve as an indication of document relevance for users, as the list 
        of keywords can quickly help to determine whether a given document is relevant to their interest. 
        As keywords reflect a document's main topics, they can be utilized to classify documents into groups 
        by measuring the overlap between the keywords assigned to them. Keywords are also used proactively 
        in information retrieval."""]
        
# Init default vectorizer for the English language that computes tf-idf values
vectorizer = KeyphraseTfidfVectorizer()

# Print parameters
print(vectorizer.get_params())
>>> {'binary': False, 'dtype': <class 'numpy.float64'>, 'lowercase': True, 'max_df': None, 'min_df': None, 'norm': 'l2', 'pos_pattern': '<J.*>*<N.*>+', 'smooth_idf': True, 'spacy_pipeline': 'en_core_web_sm', 'stop_words': 'english', 'sublinear_tf': False, 'use_idf': True, 'workers': 1}
```

To calculate tf values instead, set `use_idf=False`.

```python
# Fit and transform to document-keyphrase matrix.
document_keyphrase_matrix = vectorizer.fit_transform(docs).toarray()

print(document_keyphrase_matrix)
>>> [[0.         0.         0.09245003 0.09245003 0.09245003 0.09245003
  0.2773501  0.09245003 0.2773501  0.2773501  0.09245003 0.
  0.         0.09245003 0.         0.2773501  0.09245003 0.09245003
  0.         0.09245003 0.09245003 0.09245003 0.09245003 0.09245003
  0.5547002  0.         0.         0.09245003 0.09245003 0.
  0.2773501  0.18490007 0.09245003 0.         0.2773501  0.
  0.         0.09245003 0.         0.09245003 0.         0.
  0.         0.18490007 0.        ]
 [0.11867817 0.11867817 0.         0.         0.         0.
  0.         0.         0.         0.         0.         0.11867817
  0.11867817 0.         0.11867817 0.         0.         0.
  0.11867817 0.         0.         0.         0.         0.
  0.         0.11867817 0.23735633 0.         0.         0.11867817
  0.         0.         0.         0.23735633 0.         0.11867817
  0.11867817 0.         0.59339083 0.         0.11867817 0.11867817
  0.11867817 0.         0.59339083]]
```

```python
# Return keyphrases
keyphrases = vectorizer.get_feature_names_out()

print(keyphrases)
>>> ['various applications' 'list' 'task' 'supervisory signal'
 'inductive bias' 'supervised learning algorithm' 'supervised learning'
 'example input' 'input' 'algorithm' 'set' 'precise summary' 'documents'
 'input object' 'interest' 'function' 'class labels' 'machine'
 'document content' 'output pairs' 'new examples' 'unseen situations'
 'vector' 'output value' 'learning' 'document relevance' 'main topics'
 'pair' 'training examples' 'information retrieval environment'
 'training data' 'example' 'optimal scenario' 'information retrieval'
 'output' 'groups' 'indication' 'unseen instances' 'keywords' 'way'
 'phrases' 'overlap' 'users' 'learning algorithm' 'document']
```

<a name="##custom-pos-tagger"/></a>

### Custom POS-tagger

[Back to Table of Contents](#toc)

To use a different part-of-speech tagger than the ones provided by spaCy, a custom POS-tagger function can be defined and passed to the KeyphraseVectorizers via the `custom_pos_tagger` parameter. This parameter expects a callable function which in turn needs to expect a list of strings in a 'raw_documents' parameter and has to return a list of (word token, POS-tag) tuples. If this parameter is not None, the custom tagger function is used to tag words with parts-of-speech, while the spaCy pipeline is ignored.

#### Example using flair:

Flair can be installed via `pip install flair`.

```python
from typing import List
import flair
from flair.models import SequenceTagger
from flair.tokenization import SegtokSentenceSplitter


docs = ["""Supervised learning is the machine learning task of learning a function that
         maps an input to an output based on example input-output pairs. It infers a
         function from labeled training data consisting of a set of training examples.
         In supervised learning, each example is a pair consisting of an input object
         (typically a vector) and a desired output value (also called the supervisory signal). 
         A supervised learning algorithm analyzes the training data and produces an inferred function, 
         which can be used for mapping new examples. An optimal scenario will allow for the 
         algorithm to correctly determine the class labels for unseen instances. This requires 
         the learning algorithm to generalize from the training data to unseen situations in a 
         'reasonable' way (see inductive bias).""", 
             
        """Keywords are defined as phrases that capture the main topics discussed in a document. 
        As they offer a brief yet precise summary of document content, they can be utilized for various applications. 
        In an information retrieval environment, they serve as an indication of document relevance for users, as the list 
        of keywords can quickly help to determine whether a given document is relevant to their interest. 
        As keywords reflect a document's main topics, they can be utilized to classify documents into groups 
        by measuring the overlap between the keywords assigned to them. Keywords are also used proactively 
        in information retrieval."""]

# define flair POS-tagger and splitter
tagger = SequenceTagger.load('pos')
splitter = SegtokSentenceSplitter()

# define custom POS-tagger function using flair
def custom_pos_tagger(raw_documents: List[str], tagger: flair.models.SequenceTagger = tagger, splitter: flair.tokenization.SegtokSentenceSplitter = splitter)->List[tuple]:
    """
    Important: 

    The mandatory 'raw_documents' parameter can NOT be named differently and has to expect a list of strings. 
    Any other parameter of the custom POS-tagger function can be arbitrarily defined, depending on the respective use case. 
    Furthermore the function has to return a list of (word token, POS-tag) tuples.
    """ 
    # split texts into sentences
    sentences = []
    for doc in raw_documents:
        sentences.extend(splitter.split(doc))

    # predict POS tags
    tagger.predict(sentences)

    # iterate through sentences to get word tokens and predicted POS-tags
    pos_tags = []
    words = []
    for sentence in sentences:
        pos_tags.extend([label.value for label in sentence.get_labels('pos')])
        words.extend([word.text for word in sentence])
    
    return list(zip(words, pos_tags))


# check that the custom POS-tagger function returns a list of (word token, POS-tag) tuples
print(custom_pos_tagger(raw_documents=docs))

>>> [('Supervised', 'VBN'), ('learning', 'NN'), ('is', 'VBZ'), ('the', 'DT'), ('machine', 'NN'), ('learning', 'VBG'), ('task', 'NN'), ('of', 'IN'), ('learning', 'VBG'), ('a', 'DT'), ('function', 'NN'), ('that', 'WDT'), ('maps', 'VBZ'), ('an', 'DT'), ('input', 'NN'), ('to', 'IN'), ('an', 'DT'), ('output', 'NN'), ('based', 'VBN'), ('on', 'IN'), ('example', 'NN'), ('input-output', 'NN'), ('pairs', 'NNS'), ('.', '.'), ('It', 'PRP'), ('infers', 'VBZ'), ('a', 'DT'), ('function', 'NN'), ('from', 'IN'), ('labeled', 'VBN'), ('training', 'NN'), ('data', 'NNS'), ('consisting', 'VBG'), ('of', 'IN'), ('a', 'DT'), ('set', 'NN'), ('of', 'IN'), ('training', 'NN'), ('examples', 'NNS'), ('.', '.'), ('In', 'IN'), ('supervised', 'JJ'), ('learning', 'NN'), (',', ','), ('each', 'DT'), ('example', 'NN'), ('is', 'VBZ'), ('a', 'DT'), ('pair', 'NN'), ('consisting', 'VBG'), ('of', 'IN'), ('an', 'DT'), ('input', 'NN'), ('object', 'NN'), ('(', ':'), ('typically', 'RB'), ('a', 'DT'), ('vector', 'NN'), (')', ','), ('and', 'CC'), ('a', 'DT'), ('desired', 'VBN'), ('output', 'NN'), ('value', 'NN'), ('(', ','), ('also', 'RB'), ('called', 'VBN'), ('the', 'DT'), ('supervisory', 'JJ'), ('signal', 'NN'), (')', '-RRB-'), ('.', '.'), ('A', 'DT'), ('supervised', 'JJ'), ('learning', 'NN'), ('algorithm', 'NN'), ('analyzes', 'VBZ'), ('the', 'DT'), ('training', 'NN'), ('data', 'NNS'), ('and', 'CC'), ('produces', 'VBZ'), ('an', 'DT'), ('inferred', 'JJ'), ('function', 'NN'), (',', ','), ('which', 'WDT'), ('can', 'MD'), ('be', 'VB'), ('used', 'VBN'), ('for', 'IN'), ('mapping', 'VBG'), ('new', 'JJ'), ('examples', 'NNS'), ('.', '.'), ('An', 'DT'), ('optimal', 'JJ'), ('scenario', 'NN'), ('will', 'MD'), ('allow', 'VB'), ('for', 'IN'), ('the', 'DT'), ('algorithm', 'NN'), ('to', 'TO'), ('correctly', 'RB'), ('determine', 'VB'), ('the', 'DT'), ('class', 'NN'), ('labels', 'NNS'), ('for', 'IN'), ('unseen', 'JJ'), ('instances', 'NNS'), ('.', '.'), ('This', 'DT'), ('requires', 'VBZ'), ('the', 'DT'), ('learning', 'NN'), ('algorithm', 'NN'), ('to', 'TO'), ('generalize', 'VB'), ('from', 'IN'), ('the', 'DT'), ('training', 'NN'), ('data', 'NNS'), ('to', 'IN'), ('unseen', 'JJ'), ('situations', 'NNS'), ('in', 'IN'), ('a', 'DT'), ("'", '``'), ('reasonable', 'JJ'), ("'", "''"), ('way', 'NN'), ('(', ','), ('see', 'VB'), ('inductive', 'JJ'), ('bias', 'NN'), (')', '-RRB-'), ('.', '.'), ('Keywords', 'NNS'), ('are', 'VBP'), ('defined', 'VBN'), ('as', 'IN'), ('phrases', 'NNS'), ('that', 'WDT'), ('capture', 'VBP'), ('the', 'DT'), ('main', 'JJ'), ('topics', 'NNS'), ('discussed', 'VBN'), ('in', 'IN'), ('a', 'DT'), ('document', 'NN'), ('.', '.'), ('As', 'IN'), ('they', 'PRP'), ('offer', 'VBP'), ('a', 'DT'), ('brief', 'JJ'), ('yet', 'CC'), ('precise', 'JJ'), ('summary', 'NN'), ('of', 'IN'), ('document', 'NN'), ('content', 'NN'), (',', ','), ('they', 'PRP'), ('can', 'MD'), ('be', 'VB'), ('utilized', 'VBN'), ('for', 'IN'), ('various', 'JJ'), ('applications', 'NNS'), ('.', '.'), ('In', 'IN'), ('an', 'DT'), ('information', 'NN'), ('retrieval', 'NN'), ('environment', 'NN'), (',', ','), ('they', 'PRP'), ('serve', 'VBP'), ('as', 'IN'), ('an', 'DT'), ('indication', 'NN'), ('of', 'IN'), ('document', 'NN'), ('relevance', 'NN'), ('for', 'IN'), ('users', 'NNS'), (',', ','), ('as', 'IN'), ('the', 'DT'), ('list', 'NN'), ('of', 'IN'), ('keywords', 'NNS'), ('can', 'MD'), ('quickly', 'RB'), ('help', 'VB'), ('to', 'TO'), ('determine', 'VB'), ('whether', 'IN'), ('a', 'DT'), ('given', 'VBN'), ('document', 'NN'), ('is', 'VBZ'), ('relevant', 'JJ'), ('to', 'IN'), ('their', 'PRP$'), ('interest', 'NN'), ('.', '.'), ('As', 'IN'), ('keywords', 'NNS'), ('reflect', 'VBP'), ('a', 'DT'), ('document', 'NN'), ("'s", 'POS'), ('main', 'JJ'), ('topics', 'NNS'), (',', ','), ('they', 'PRP'), ('can', 'MD'), ('be', 'VB'), ('utilized', 'VBN'), ('to', 'TO'), ('classify', 'VB'), ('documents', 'NNS'), ('into', 'IN'), ('groups', 'NNS'), ('by', 'IN'), ('measuring', 'VBG'), ('the', 'DT'), ('overlap', 'NN'), ('between', 'IN'), ('the', 'DT'), ('keywords', 'NNS'), ('assigned', 'VBN'), ('to', 'IN'), ('them', 'PRP'), ('.', '.'), ('Keywords', 'NNS'), ('are', 'VBP'), ('also', 'RB'), ('used', 'VBN'), ('proactively', 'RB'), ('in', 'IN'), ('information', 'NN'), ('retrieval', 'NN'), ('.', '.')]
```

After the custom POS-tagger function is defined, it can be passed to KeyphraseVectorizers via the `custom_pos_tagger` parameter.

```python
from keyphrase_vectorizers import KeyphraseCountVectorizer

# use custom POS-tagger with KeyphraseVectorizers
vectorizer = KeyphraseCountVectorizer(custom_pos_tagger=custom_pos_tagger)
vectorizer.fit(docs)
keyphrases = vectorizer.get_feature_names_out()
print(keyphrases)

>>>['output value' 'information retrieval' 'algorithm' 'vector' 'groups'
 'main topics' 'task' 'precise summary' 'supervised learning'
 'inductive bias' 'information retrieval environment'
 'supervised learning algorithm' 'function' 'input' 'pair'
 'document relevance' 'learning' 'class labels' 'new examples' 'keywords'
 'list' 'machine' 'training data' 'unseen situations' 'phrases' 'output'
 'optimal scenario' 'document' 'training examples' 'documents' 'interest'
 'indication' 'learning algorithm' 'inferred function'
 'various applications' 'example' 'set' 'unseen instances'
 'example input-output pairs' 'way' 'users' 'input object'
 'supervisory signal' 'overlap' 'document content']
```

<a name="#keyphrase-extraction-with-keybert"/></a>

### Keyphrase extraction with [KeyBERT](https://github.com/MaartenGr/KeyBERT "KeyBERT repository")

[Back to Table of Contents](#toc)

The keyphrase vectorizers can be used together with KeyBERT to extract grammatically correct keyphrases that are most
similar to a document. Thereby, the vectorizer first extracts candidate keyphrases from the text documents, which are
subsequently ranked by KeyBERT based on their document similarity. The top-n most similar keyphrases can then be
considered as document keywords.

The advantage of using KeyphraseVectorizers in addition to KeyBERT is that it allows users to get grammatically correct
keyphrases instead of simple n-grams of pre-defined lengths. In KeyBERT, users can specify the `keyphrase_ngram_range`
to define the length of the retrieved keyphrases. However, this raises two issues. First, users usually do not know the
optimal n-gram range and therefore have to spend some time experimenting until they find a suitable n-gram range.
Second, even after finding a good n-gram range, the returned keyphrases are sometimes still grammatically not quite
correct or are slightly off-key. Unfortunately, this limits the quality of the returned keyphrases.

To adress this issue, we can use the vectorizers of this package to first extract candidate keyphrases that consist of
zero or more adjectives, followed by one or multiple nouns in a pre-processing step instead of simple n-grams.
[Wan and Xiao](https://www.aaai.org/Papers/AAAI/2008/AAAI08-136.pdf) successfully used this noun phrase approach for
keyphrase extraction during their research in 2008. The extracted candidate keyphrases are subsequently passed to
KeyBERT for embedding generation and similarity calculation. To use both packages for keyphrase extraction, we need to
pass KeyBERT a keyphrase vectorizer with the `vectorizer` parameter. Since the length of keyphrases now depends on
part-of-speech tags, there is no need to define an n-gram length anymore.

#### Example:

KeyBERT can be installed via `pip install keybert`.

```python
from keyphrase_vectorizers import KeyphraseCountVectorizer
from keybert import KeyBERT

docs = ["""Supervised learning is the machine learning task of learning a function that
         maps an input to an output based on example input-output pairs. It infers a
         function from labeled training data consisting of a set of training examples.
         In supervised learning, each example is a pair consisting of an input object
         (typically a vector) and a desired output value (also called the supervisory signal). 
         A supervised learning algorithm analyzes the training data and produces an inferred function, 
         which can be used for mapping new examples. An optimal scenario will allow for the 
         algorithm to correctly determine the class labels for unseen instances. This requires 
         the learning algorithm to generalize from the training data to unseen situations in a 
         'reasonable' way (see inductive bias).""", 
             
        """Keywords are defined as phrases that capture the main topics discussed in a document. 
        As they offer a brief yet precise summary of document content, they can be utilized for various applications. 
        In an information retrieval environment, they serve as an indication of document relevance for users, as the list 
        of keywords can quickly help to determine whether a given document is relevant to their interest. 
        As keywords reflect a document's main topics, they can be utilized to classify documents into groups 
        by measuring the overlap between the keywords assigned to them. Keywords are also used proactively 
        in information retrieval."""]

kw_model = KeyBERT()
```

Instead of deciding on a suitable n-gram range which could be e.g.(1,2)...

```python
>>> kw_model.extract_keywords(docs=docs, keyphrase_ngram_range=(1,2))
[[('labeled training', 0.6013),
  ('examples supervised', 0.6112),
  ('signal supervised', 0.6152),
  ('supervised', 0.6676),
  ('supervised learning', 0.6779)],
 [('keywords assigned', 0.6354),
  ('keywords used', 0.6373),
  ('list keywords', 0.6375),
  ('keywords quickly', 0.6376),
  ('keywords defined', 0.6997)]]
```

we can now just let the keyphrase vectorizer decide on suitable keyphrases, without limitations to a maximum or minimum
n-gram range. We only have to pass a keyphrase vectorizer as parameter to KeyBERT:

```python
>>> kw_model.extract_keywords(docs=docs, vectorizer=KeyphraseCountVectorizer())
[[('learning', 0.4813), 
  ('training data', 0.5271), 
  ('learning algorithm', 0.5632), 
  ('supervised learning', 0.6779), 
  ('supervised learning algorithm', 0.6992)], 
 [('document content', 0.3988), 
  ('information retrieval environment', 0.5166), 
  ('information retrieval', 0.5792), 
  ('keywords', 0.6046), 
  ('document relevance', 0.633)]]
```

This allows us to make sure that we do not cut off important words caused by defining our n-gram range too short. For
example, we would not have found the keyphrase "supervised learning algorithm" with `keyphrase_ngram_range=(1,2)`.
Furthermore, we avoid to get keyphrases that are slightly off-key like "labeled training", "signal supervised" or
"keywords quickly".

For more tips on how to use the KeyphraseVectorizers together with KeyBERT, visit [this guide](https://maartengr.github.io/KeyBERT/guides/countvectorizer.html#keyphrasevectorizers "KeyBERT rCountVectorizer Guide").

<a name="#topic-modeling-with-bertopic-and-keyphrasevectorizers"/></a>

### Topic modeling with [BERTopic](https://github.com/MaartenGr/BERTopic "BERTopic repository") and KeyphraseVectorizers

[Back to Table of Contents](#toc)

Similar to the application with KeyBERT, the keyphrase vectorizers can be used to obtain grammatically correct keyphrases as
descriptions for topics instead of simple n-grams. This allows us to make sure that we do not cut off important topic
description keyphrases by defining our n-gram range too short. Moreover, we don't need to clean stopwords upfront, can
get more precise topic models and avoid to get topic description keyphrases that are slightly off-key.

#### Example:

BERTopic can be installed via `pip install bertopic`.

```python
from keyphrase_vectorizers import KeyphraseCountVectorizer
from bertopic import BERTopic
from sklearn.datasets import fetch_20newsgroups

# load text documents
docs = fetch_20newsgroups(subset='all',  remove=('headers', 'footers', 'quotes'))['data']
# only use subset of the data 
docs = docs[:5000]

# train topic model with KeyphraseCountVectorizer
keyphrase_topic_model = BERTopic(vectorizer_model=KeyphraseCountVectorizer())
keyphrase_topics, keyphrase_probs = keyphrase_topic_model.fit_transform(docs)

# get topics
>>> keyphrase_topic_model.topics
{-1: [('file', 0.007265527630674131),
  ('one', 0.007055454904474792),
  ('use', 0.00633563957153475),
  ('program', 0.006053271092949018),
  ('get', 0.006011060091056076),
  ('people', 0.005729309058970368),
  ('know', 0.005635951168273583),
  ('like', 0.0055692449802916015),
  ('time', 0.00527028825803415),
  ('us', 0.00525564504880084)],
 0: [('game', 0.024134589719090525),
  ('team', 0.021852806383170772),
  ('players', 0.01749406934044139),
  ('games', 0.014397938026886745),
  ('hockey', 0.013932342023677305),
  ('win', 0.013706115572901401),
  ('year', 0.013297593024390321),
  ('play', 0.012533185558169046),
  ('baseball', 0.012412743802062559),
  ('season', 0.011602725885164318)],
 1: [('patients', 0.022600352291162015),
  ('msg', 0.02023877371575874),
  ('doctor', 0.018816282737587457),
  ('medical', 0.018614407917995103),
  ('treatment', 0.0165028251400717),
  ('food', 0.01604980195180696),
  ('candida', 0.015255961242066143),
  ('disease', 0.015115496310099693),
  ('pain', 0.014129703072484495),
  ('hiv', 0.012884503220341102)],
 2: [('key', 0.028851633177510126),
  ('encryption', 0.024375137861044675),
  ('clipper', 0.023565947302544528),
  ('privacy', 0.019258719348097385),
  ('security', 0.018983682856076434),
  ('chip', 0.018822199098878365),
  ('keys', 0.016060139239615384),
  ('internet', 0.01450486904722165),
  ('encrypted', 0.013194373119964168),
  ('government', 0.01303978311708837)],
  ...
```

The same topics look a bit different when no keyphrase vectorizer is used:

```python
from bertopic import BERTopic
from sklearn.datasets import fetch_20newsgroups

# load text documents
docs = fetch_20newsgroups(subset='all',  remove=('headers', 'footers', 'quotes'))['data']
# only use subset of the data 
docs = docs[:5000]

# train topic model without KeyphraseCountVectorizer
topic_model = BERTopic()
topics, probs = topic_model.fit_transform(docs)

# get topics
>>> topic_model.topics
{-1: [('the', 0.012864641020408933),
  ('to', 0.01187920529994724),
  ('and', 0.011431498631699856),
  ('of', 0.01099851927541331),
  ('is', 0.010995478673036962),
  ('in', 0.009908233622158523),
  ('for', 0.009903667215879675),
  ('that', 0.009619596716087699),
  ('it', 0.009578499681829809),
  ('you', 0.0095328846440753)],
 0: [('game', 0.013949166096523719),
  ('team', 0.012458483177116456),
  ('he', 0.012354733462693834),
  ('the', 0.01119583508278812),
  ('10', 0.010190243555226108),
  ('in', 0.0101436249231417),
  ('players', 0.009682212470082758),
  ('to', 0.00933700544705287),
  ('was', 0.009172402203816335),
  ('and', 0.008653375901739337)],
 1: [('of', 0.012771267188340924),
  ('to', 0.012581337590513296),
  ('is', 0.012554884458779008),
  ('patients', 0.011983273578628046),
  ('and', 0.011863499662237566),
  ('that', 0.011616113472989725),
  ('it', 0.011581944987387165),
  ('the', 0.011475148304229873),
  ('in', 0.011395485985801054),
  ('msg', 0.010715000656335596)],
 2: [('key', 0.01725282988290282),
  ('the', 0.014634841495851404),
  ('be', 0.014429762197907552),
  ('encryption', 0.013530733999898166),
  ('to', 0.013443159534369817),
  ('clipper', 0.01296614319927958),
  ('of', 0.012164734232650158),
  ('is', 0.012128295958613464),
  ('and', 0.011972763728732667),
  ('chip', 0.010785744492767285)],
 ...
```
