Difference between revisions of "Koo and Collins ACL 2010"
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This [[Category::paper]] presents a higher-order [[AddressesProblem::Dependency Parsing|dependency parser]] that can evaluate substructures containing three dependencies, using both sibling-style and grandchild-style interactions. The algorithms presented require only <math>O(n^4)</math> time and were evaluated on the [[UsesDataset::Penn Treebank]] and the [[UsesDataset::Prague Dependency Treebank]]. The implementation code was publicly released [http://groups.csail.mit.edu/nlp/dpo3/]. | This [[Category::paper]] presents a higher-order [[AddressesProblem::Dependency Parsing|dependency parser]] that can evaluate substructures containing three dependencies, using both sibling-style and grandchild-style interactions. The algorithms presented require only <math>O(n^4)</math> time and were evaluated on the [[UsesDataset::Penn Treebank]] and the [[UsesDataset::Prague Dependency Treebank]]. The implementation code was publicly released [http://groups.csail.mit.edu/nlp/dpo3/]. | ||
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| + | === Background === | ||
Dependency parsing is defined as a search for the highest-scoring analysis of a sentence <math>\, x</math>: | Dependency parsing is defined as a search for the highest-scoring analysis of a sentence <math>\, x</math>: | ||
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<math>\textrm{Score}(x,y) = \sum_{p \in y}\textrm{ScorePart}(x,p)</math> | <math>\textrm{Score}(x,y) = \sum_{p \in y}\textrm{ScorePart}(x,p)</math> | ||
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| + | The ''order'' of a part is defined according to the number of dependencies it contains, a terminology used in previous parsing algorithms, such as first-order factorization and second-order sibling factorization. The factorizations in this new third-order parser uses the following parts: | ||
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| + | [[File:dpo3_001.png]] | ||
== Experimental results == | == Experimental results == | ||
Revision as of 21:34, 25 November 2011
Contents
Citation
Koo, T. and Collins, M. 2010. Efficient Third-Order Dependency Parsers. In Proceedings of ACL, pp. 1-11. Association for Computational Linguistics.
Online version
Summary
This paper presents a higher-order dependency parser that can evaluate substructures containing three dependencies, using both sibling-style and grandchild-style interactions. The algorithms presented require only time and were evaluated on the Penn Treebank and the Prague Dependency Treebank. The implementation code was publicly released [1].
Background
Dependency parsing is defined as a search for the highest-scoring analysis of a sentence :
where is the set of all trees compatible with and evaluates the event that tree is the analysis of . Directly solving the equation is unfeasible because the number of possible trees grow exponentially with the length of the sentence. A common strategy is to factor each dependency tree into small parts which can be scored individually, then:
The order of a part is defined according to the number of dependencies it contains, a terminology used in previous parsing algorithms, such as first-order factorization and second-order sibling factorization. The factorizations in this new third-order parser uses the following parts:
Experimental results
Bla bla.
Related papers
Bla bla.
