Difference between revisions of "Minimum error rate training"

Minimum error rate training (or MERT) is a method. This is a work in progress by Francis Keith

Citation

MERT was originally proposed in the paper “Minimum Error Rate Training in Statistical Machine Translation”, Franz Josef Och, ACL, 2003, pp. 160-167. (found here [1])

Background

When training a model, often times it is beneficial to take into account the actual evaluation method for that model. In many cases, training methods do not. MERT attempts to train models for statistical machine translation. It attempts to optimize the parameters of the model while considering a more complex evaluation method than simply counting incorrect translations. It essentially attempts to train the model based on the method that will be used to evaluate the model.

Optimization Problem

The goal of MERT, as the name would suggest, is to find a minimum error rate count, given:

• ${\displaystyle f_{1}^{s}}$, the representative corpus
• ${\displaystyle {\hat {e}}_{1}^{s}}$, the reference translations
• ${\displaystyle K}$, a set of candidate translations
  • ${\displaystyle C_{s}=\{e_{s,1},...,e_{s,K}\}}$ for each ${\displaystyle f_{s}}$
• ${\displaystyle M}$ feature functions ${\displaystyle h_{m}(e,f)}$
• ${\displaystyle M}$ model parameters ${\displaystyle \lambda _{m}}$

We then attempt to optimize:

${\displaystyle {\hat {e}}(f_{s};\lambda _{1}^{M})={\underset {e\in C}{\operatorname {argmax} }}\{\sum _{m=1}^{M}\lambda _{m}h_{m}(e|f_{s})\}}$

The error count is provided by:

${\displaystyle {\hat {\lambda }}_{1}^{M}={\underset {\lambda _{1}^{M}}{\operatorname {argmin} }}\{\sum _{s=1}^{S}E(r_{s},{\hat {e}}(f_{s};\lambda _{1}^{m}))\}}$ ${\displaystyle ={\underset {\lambda _{1}^{M}}{\operatorname {argmin} }}\{\sum _{s=1}^{S}\sum _{k=1}^{K}E(r_{s},e_{s,k})\delta ({\hat {e}}(f_{s};\lambda _{1}^{M}),e_{s,k})\}}$

Drawbacks

MERT, while very powerful (and the current popular approach to training MT models), has some drawbacks

• Tends to overfit
• Doesn't work well with large feature sets
• High variance across runs due to many local optima