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243 lines
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243 lines
8.0 KiB
Plaintext
.. Copyright (C) 2001-2019 NLTK Project
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.. For license information, see LICENSE.TXT
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.. -*- coding: utf-8 -*-
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=========
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Alignment
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=========
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Corpus Reader
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-------------
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>>> from nltk.corpus import comtrans
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>>> words = comtrans.words('alignment-en-fr.txt')
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>>> for word in words[:6]:
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... print(word)
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Resumption
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of
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the
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session
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I
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declare
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>>> als = comtrans.aligned_sents('alignment-en-fr.txt')[0]
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>>> als # doctest: +NORMALIZE_WHITESPACE
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AlignedSent(['Resumption', 'of', 'the', 'session'],
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['Reprise', 'de', 'la', 'session'],
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Alignment([(0, 0), (1, 1), (2, 2), (3, 3)]))
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Alignment Objects
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-----------------
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Aligned sentences are simply a mapping between words in a sentence:
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>>> print(" ".join(als.words))
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Resumption of the session
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>>> print(" ".join(als.mots))
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Reprise de la session
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>>> als.alignment
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Alignment([(0, 0), (1, 1), (2, 2), (3, 3)])
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Usually we look at them from the perspective of a source to a target language,
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but they are easily inverted:
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>>> als.invert() # doctest: +NORMALIZE_WHITESPACE
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AlignedSent(['Reprise', 'de', 'la', 'session'],
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['Resumption', 'of', 'the', 'session'],
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Alignment([(0, 0), (1, 1), (2, 2), (3, 3)]))
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We can create new alignments, but these need to be in the correct range of
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the corresponding sentences:
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>>> from nltk.translate import Alignment, AlignedSent
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>>> als = AlignedSent(['Reprise', 'de', 'la', 'session'],
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... ['Resumption', 'of', 'the', 'session'],
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... Alignment([(0, 0), (1, 4), (2, 1), (3, 3)]))
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Traceback (most recent call last):
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...
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IndexError: Alignment is outside boundary of mots
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You can set alignments with any sequence of tuples, so long as the first two
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indexes of the tuple are the alignment indices:
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>>> als.alignment = Alignment([(0, 0), (1, 1), (2, 2, "boat"), (3, 3, False, (1,2))])
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>>> Alignment([(0, 0), (1, 1), (2, 2, "boat"), (3, 3, False, (1,2))])
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Alignment([(0, 0), (1, 1), (2, 2, 'boat'), (3, 3, False, (1, 2))])
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Alignment Algorithms
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--------------------
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EM for IBM Model 1
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~~~~~~~~~~~~~~~~~~
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Here is an example from Koehn, 2010:
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>>> from nltk.translate import IBMModel1
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>>> corpus = [AlignedSent(['the', 'house'], ['das', 'Haus']),
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... AlignedSent(['the', 'book'], ['das', 'Buch']),
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... AlignedSent(['a', 'book'], ['ein', 'Buch'])]
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>>> em_ibm1 = IBMModel1(corpus, 20)
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>>> print(round(em_ibm1.translation_table['the']['das'], 1))
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1.0
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>>> print(round(em_ibm1.translation_table['book']['das'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['house']['das'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['the']['Buch'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['book']['Buch'], 1))
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1.0
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>>> print(round(em_ibm1.translation_table['a']['Buch'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['book']['ein'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['a']['ein'], 1))
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1.0
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>>> print(round(em_ibm1.translation_table['the']['Haus'], 1))
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0.0
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>>> print(round(em_ibm1.translation_table['house']['Haus'], 1))
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1.0
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>>> print(round(em_ibm1.translation_table['book'][None], 1))
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0.5
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And using an NLTK corpus. We train on only 10 sentences, since it is so slow:
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>>> from nltk.corpus import comtrans
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>>> com_ibm1 = IBMModel1(comtrans.aligned_sents()[:10], 20)
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>>> print(round(com_ibm1.translation_table['bitte']['Please'], 1))
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0.2
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>>> print(round(com_ibm1.translation_table['Sitzungsperiode']['session'], 1))
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1.0
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Evaluation
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----------
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The evaluation metrics for alignments are usually not interested in the
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contents of alignments but more often the comparison to a "gold standard"
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alignment that has been been constructed by human experts. For this reason we
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often want to work just with raw set operations against the alignment points.
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This then gives us a very clean form for defining our evaluation metrics.
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.. Note::
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The AlignedSent class has no distinction of "possible" or "sure"
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alignments. Thus all alignments are treated as "sure".
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Consider the following aligned sentence for evaluation:
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>>> my_als = AlignedSent(['Resumption', 'of', 'the', 'session'],
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... ['Reprise', 'de', 'la', 'session'],
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... Alignment([(0, 0), (3, 3), (1, 2), (1, 1), (1, 3)]))
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Precision
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~~~~~~~~~
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``precision = |A∩P| / |A|``
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**Precision** is probably the most well known evaluation metric and it is implemented
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in `nltk.metrics.scores.precision`_. Since precision is simply interested in the
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proportion of correct alignments, we calculate the ratio of the number of our
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test alignments (*A*) that match a possible alignment (*P*), over the number of
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test alignments provided. There is no penalty for missing a possible alignment
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in our test alignments. An easy way to game this metric is to provide just one
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test alignment that is in *P* [OCH2000]_.
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Here are some examples:
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>>> from nltk.metrics import precision
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>>> als.alignment = Alignment([(0,0), (1,1), (2,2), (3,3)])
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>>> precision(Alignment([]), als.alignment)
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0.0
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>>> precision(Alignment([(0,0), (1,1), (2,2), (3,3)]), als.alignment)
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1.0
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>>> precision(Alignment([(0,0), (3,3)]), als.alignment)
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0.5
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>>> precision(Alignment.fromstring('0-0 3-3'), als.alignment)
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0.5
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>>> precision(Alignment([(0,0), (1,1), (2,2), (3,3), (1,2), (2,1)]), als.alignment)
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1.0
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>>> precision(als.alignment, my_als.alignment)
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0.6
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.. _nltk.metrics.scores.precision:
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http://www.nltk.org/api/nltk.metrics.html#nltk.metrics.scores.precision
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Recall
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~~~~~~
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``recall = |A∩S| / |S|``
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**Recall** is another well known evaluation metric that has a set based
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implementation in NLTK as `nltk.metrics.scores.recall`_. Since recall is
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simply interested in the proportion of found alignments, we calculate the
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ratio of the number of our test alignments (*A*) that match a sure alignment
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(*S*) over the number of sure alignments. There is no penalty for producing
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a lot of test alignments. An easy way to game this metric is to include every
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possible alignment in our test alignments, regardless if they are correct or
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not [OCH2000]_.
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Here are some examples:
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>>> from nltk.metrics import recall
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>>> print(recall(Alignment([]), als.alignment))
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None
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>>> recall(Alignment([(0,0), (1,1), (2,2), (3,3)]), als.alignment)
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1.0
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>>> recall(Alignment.fromstring('0-0 3-3'), als.alignment)
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1.0
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>>> recall(Alignment([(0,0), (3,3)]), als.alignment)
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1.0
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>>> recall(Alignment([(0,0), (1,1), (2,2), (3,3), (1,2), (2,1)]), als.alignment)
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0.66666...
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>>> recall(als.alignment, my_als.alignment)
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0.75
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.. _nltk.metrics.scores.recall:
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http://www.nltk.org/api/nltk.metrics.html#nltk.metrics.scores.recall
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Alignment Error Rate (AER)
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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``AER = 1 - (|A∩S| + |A∩P|) / (|A| + |S|)``
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**Alignment Error Rate** is commonly used metric for assessing sentence
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alignments. It combines precision and recall metrics together such that a
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perfect alignment must have all of the sure alignments and may have some
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possible alignments [MIHALCEA2003]_ [KOEHN2010]_.
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.. Note::
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[KOEHN2010]_ defines the AER as ``AER = (|A∩S| + |A∩P|) / (|A| + |S|)``
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in his book, but corrects it to the above in his online errata. This is
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in line with [MIHALCEA2003]_.
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Here are some examples:
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>>> from nltk.translate import alignment_error_rate
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>>> alignment_error_rate(Alignment([]), als.alignment)
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1.0
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>>> alignment_error_rate(Alignment([(0,0), (1,1), (2,2), (3,3)]), als.alignment)
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0.0
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>>> alignment_error_rate(als.alignment, my_als.alignment)
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0.333333...
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>>> alignment_error_rate(als.alignment, my_als.alignment,
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... als.alignment | Alignment([(1,2), (2,1)]))
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0.222222...
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.. [OCH2000] Och, F. and Ney, H. (2000)
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*Statistical Machine Translation*, EAMT Workshop
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.. [MIHALCEA2003] Mihalcea, R. and Pedersen, T. (2003)
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*An evaluation exercise for word alignment*, HLT-NAACL 2003
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.. [KOEHN2010] Koehn, P. (2010)
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*Statistical Machine Translation*, Cambridge University Press
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