@inproceedings{amponsah-kaakyire-etal-2022-explaining,
title = {Explaining Translationese: why are Neural Classifiers Better and what do they Learn?},
author = {Kwabena Amponsah-Kaakyire and Daria Pylypenko and Josef van Genabith and Cristina Espa{\~n}a-Bonet},
url = {https://aclanthology.org/2022.blackboxnlp-1.23},
doi = {https://doi.org/10.48550/ARXIV.2210.13391},
year = {2022},
date = {2022-01-19},
booktitle = {Proceedings of the Fifth BlackboxNLP Workshop on Analyzing and Interpreting Neural Networks for NLP},
pages = {281-296},
publisher = {Association for Computational Linguistics},
address = {Abu Dhabi, United Arab Emirates (Hybrid), Dec 2022},
abstract = {Recent work has shown that neural feature- and representation-learning, e.g. BERT, achieves superior performance over traditional manual feature engineering based approaches, with e.g. SVMs, in translationese classification tasks. Previous research did not show <span id="MathJax-Element-1-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-1" class="math"><span id="MathJax-Span-2" class="mrow"><span id="MathJax-Span-3" class="mo">(</span><span id="MathJax-Span-4" class="mi">i</span><span id="MathJax-Span-5" class="mo">)</span></span></span></span> whether the difference is because of the features, the classifiers or both, and <span id="MathJax-Element-2-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-6" class="math"><span id="MathJax-Span-7" class="mrow"><span id="MathJax-Span-8" class="mo">(</span><span id="MathJax-Span-9" class="mi">i</span><span id="MathJax-Span-10" class="mi">i</span><span id="MathJax-Span-11" class="mo">)</span></span></span></span> what the neural classifiers actually learn. To address <span id="MathJax-Element-3-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-12" class="math"><span id="MathJax-Span-13" class="mrow"><span id="MathJax-Span-14" class="mo">(</span><span id="MathJax-Span-15" class="mi">i</span><span id="MathJax-Span-16" class="mo">)</span></span></span></span>, we carefully design experiments that swap features between BERT- and SVM-based classifiers. We show that an SVM fed with BERT representations performs at the level of the best BERT classifiers, while BERT learning and using handcrafted features performs at the level of an SVM using handcrafted features. This shows that the performance differences are due to the features. To address <span id="MathJax-Element-4-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-17" class="math"><span id="MathJax-Span-18" class="mrow"><span id="MathJax-Span-19" class="mo">(</span><span id="MathJax-Span-20" class="mi">i</span><span id="MathJax-Span-21" class="mi">i</span><span id="MathJax-Span-22" class="mo">)</span></span></span></span> we use integrated gradients and find that <span id="MathJax-Element-5-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-23" class="math"><span id="MathJax-Span-24" class="mrow"><span id="MathJax-Span-25" class="mo">(</span><span id="MathJax-Span-26" class="mi">a</span><span id="MathJax-Span-27" class="mo">)</span></span></span></span> there is indication that information captured by hand-crafted features is only a subset of what BERT learns, and <span id="MathJax-Element-6-Frame" class="MathJax" tabindex="0"><span id="MathJax-Span-28" class="math"><span id="MathJax-Span-29" class="mrow"><span id="MathJax-Span-30" class="mo">(</span><span id="MathJax-Span-31" class="mi">b</span><span id="MathJax-Span-32" class="mo">)</span></span></span></span> part of BERT's top performance results are due to BERT learning topic differences and spurious correlations with translationese.},
pubstate = {published},
type = {inproceedings}
}