summaryrefslogtreecommitdiff
path: root/report/introduction.tex
diff options
context:
space:
mode:
Diffstat (limited to 'report/introduction.tex')
-rw-r--r--report/introduction.tex47
1 files changed, 0 insertions, 47 deletions
diff --git a/report/introduction.tex b/report/introduction.tex
index 12cc2705..41d1e81b 100644
--- a/report/introduction.tex
+++ b/report/introduction.tex
@@ -122,50 +122,3 @@ The algorithms we explored were Maximum Expected Bleu \cite{smith,li} and MIRA \
Chapter \ref{chap:training} describes this work.
The remainder of this introductory chapter provides a formal definition of SCFGs and describes the language pairs that we experimented with.
-
-\section{Synchronous context free grammar} \label{sec:scfg}
-{\em This section will be moved to the start of Chapter 2}
-
-%\subsubsection*{Synchronous context free grammar} \label{sec:scfg}
-\begin{figure}[t]
-\begin{center}
-\includegraphics[width=0.6\columnwidth]{example_derivation2.pdf}
-\end{center}
-\caption[Derivation]{An example SCFG derivation from a Chinese source sentence which yields the English sentence: {\em ``Brown arrived in Shanghai from Beijing late last night.''}. The non-terminal alignment $\mathbf{a}$ is specified by the variable subscripts.}
-\label{fig:intro_example_derivation}
-\end{figure}
-
-The translation models discussed explored in this workshop are based on synchronous grammars.
-Here we provide a short definition of the formalism we've employed: synchronous context free grammar (SCFG).
-
-A synchronous context free grammar (SCFG, \cite{lewis68scfg}) generalizes context-free grammars to generate strings concurrently in two (or more) languages. A string pair is generated by applying a series of paired rewrite rules of the form, $X \rightarrow \langle \mathbf{e}, \mathbf{f}, \mathbf{a} \rangle$, where $X$ is a non-terminal, $\mathbf{e}$ and $\mathbf{f}$ are strings of terminals and non-terminals and $\mathbf{a}$ specifies a one-to-one alignment between non-terminals in $\mathbf{e}$ and $\mathbf{f}$.
-In the context of SMT, by assigning the source and target languages to the respective sides of a probabilistic SCFG it is possible to describe translation as the process of parsing the source sentence, which induces a parallel tree structure and translation in the target language \cite{chiang07hierarchical}.
-Terminal are rewritten as pairs of strings of terminal symbols in the source and target languages. Additionally, one side of a terminal expansion may be the special symbol $\epsilon$, which indicates a null alignment which permits arbitrary insertions and deletions.
-Figure \ref{fig:intro_example_derivation} is an example derivation for Chinese to English translation using an SCFG of the form that I propose to learn using non-parametric Bayesian models.
-
-The generative story is as follows.
-In the beginning was the grammar, in which we allow two types of rules: {\emph non-terminal} and {\emph terminal} expansions.
-The former rewrites a non-terminal symbol as a string of two or three non-terminals along with an alignment $\mathbf{a}$, specifying the corresponding ordering of the child trees in the source and target language.
-Terminal expansion rewrite a non-terminal as a pair of terminal n-grams, where either but not both may be empty.
-Given a grammar, each sentence is generated as follows, starting with the distinguished root non-terminal, $S$.
-Rewrite each frontier non-terminal, $c$, using a rule chosen from our grammar expanding $c$.
-Repeat until there are no remaining frontier non-terminals.
-The sentences in both languages can then be read off the leaves, using the rules' alignments to find the right ordering.
-
-\begin{figure}[t]
- \centering
- \subfigure{\includegraphics[scale=0.7]{intro_slides/PhraseExtraction1.pdf}}
- \subfigure{\includegraphics[scale=0.7]{intro_slides/HieroExtraction2.pdf}}
-\caption{Extracting translation rules from aligned sentences. All the phrases obtained using the standard phrase extraction heuristics are depicted in the left figure, these are: $\langle$ Je, I $\rangle$, $\langle$ veux, want to $\rangle$, $\langle$ travailler, work $\rangle$, $\langle$ ne veux pas, do not want to $\rangle$, $\langle$ ne veux pas travailler, do not want to work $\rangle$, $\langle$ Je ne veux pas, I do not want to $\rangle$, $\langle$ Je ne veux pas travailler, I do not want to work $\rangle$. On the right is shown how a discontiguous SCFG rule is created by generalising a phrase embedded in another phrase, the extracted rule is: X $\rightarrow$ $\langle$ ne X$_1$ pas, do not X$_1$ $\rangle$.}
-\label{fig:intro_rule_extraction}
-\end{figure}
-
-The process for extracting SCFG rules is based on that used to extract translation phrases in phrase based translation systems.
-The phrase based approach \cite{koehn03} uses heuristics to extract phrase translation pairs from a word-aligned corpus.
-The phrase extraction heuristic is illustrated in Figure \ref{fig:intro_rule_extraction}.
-This heuristic extracts all phrases whose words are either not aligned, or aligned with only other words in the same phrase.
-The phrase translation probabilities are then calculated using a maximum likelihood estimation.
-
-The Hiero \cite{chiang07hierarchical} SCFG extraction heuristic starts from a grammar consisting of the set of contiguous phrases, wherever a phrase is wholly embedded within another a new rule is add with the embedded phrase replace by the non-terminal X.
-This process continues until all possible rules have been extracted, subject to the constraints that every rule must contain a terminal on the source side, a rule may only contain two non-terminals on its right side and that those non-terminals may not be adjacent.
-The left example in Figure \ref{fig:intro_rule_extraction} depicts this rule generalisation process.