|
--- |
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annotations_creators: |
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- expert-generated |
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language_creators: |
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- crowdsourced |
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language: |
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- en |
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license: |
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- apache-2.0 |
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multilinguality: |
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- monolingual |
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pretty_name: 'probability_words_nli' |
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paperwithcoode_id: probability-words-nli |
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size_categories: |
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- 1K<n<10K |
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source_datasets: |
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- original |
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task_categories: |
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- text-classification |
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- multiple-choice |
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- question-answering |
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task_ids: |
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- open-domain-qa |
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- multiple-choice-qa |
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- natural-language-inference |
|
- multi-input-text-classification |
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tags: |
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- wep |
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- words of estimative probability |
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- probability |
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- logical reasoning |
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- soft logic |
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- nli |
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- verbal probabilities |
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- natural-language-inference |
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- reasoning |
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- logic |
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train-eval-index: |
|
- config: usnli |
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task: text-classification |
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task_id: multi-class-classification |
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splits: |
|
train_split: train |
|
eval_split: validation |
|
col_mapping: |
|
sentence1: context |
|
sentence2: hypothesis |
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label: label |
|
metrics: |
|
- type: accuracy |
|
name: Accuracy |
|
- type: f1 |
|
name: F1 binary |
|
- config: reasoning-1hop |
|
task: text-classification |
|
task_id: multi-class-classification |
|
splits: |
|
train_split: train |
|
eval_split: validation |
|
col_mapping: |
|
sentence1: context |
|
sentence2: hypothesis |
|
label: label |
|
metrics: |
|
- type: accuracy |
|
name: Accuracy |
|
- type: f1 |
|
name: F1 binary |
|
- config: reasoning-2hop |
|
task: text-classification |
|
task_id: multi-class-classification |
|
splits: |
|
train_split: train |
|
eval_split: validation |
|
col_mapping: |
|
sentence1: context |
|
sentence2: hypothesis |
|
label: label |
|
metrics: |
|
- type: accuracy |
|
name: Accuracy |
|
- type: f1 |
|
name: F1 binary |
|
--- |
|
|
|
# Dataset accompanying the "Probing neural language models for understanding of words of estimative probability" article |
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|
|
This dataset tests the capabilities of language models to correctly capture the meaning of words denoting probabilities (WEP, also called verbal probabilities), e.g. words like "probably", "maybe", "surely", "impossible". |
|
|
|
We used probabilitic soft logic to combine probabilistic statements expressed with WEP (WEP-Reasoning) and we also used the UNLI dataset (https://nlp.jhu.edu/unli/) to directly check whether models can detect the WEP matching human-annotated probabilities according to [Fagen-Ulmschneider, 2018](https://github.com/wadefagen/datasets/tree/master/Perception-of-Probability-Words). |
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The dataset can be used as natural language inference data (context, premise, label) or multiple choice question answering (context,valid_hypothesis, invalid_hypothesis). |
|
|
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Code : [colab](https://colab.research.google.com/drive/10ILEWY2-J6Q1hT97cCB3eoHJwGSflKHp?usp=sharing) |
|
|
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# Citation |
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https://arxiv.org/abs/2211.03358 |
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```bib |
|
@inproceedings{sileo-moens-2023-probing, |
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title = "Probing neural language models for understanding of words of estimative probability", |
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author = "Sileo, Damien and |
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Moens, Marie-francine", |
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booktitle = "Proceedings of the 12th Joint Conference on Lexical and Computational Semantics (*SEM 2023)", |
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month = jul, |
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year = "2023", |
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address = "Toronto, Canada", |
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publisher = "Association for Computational Linguistics", |
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url = "https://aclanthology.org/2023.starsem-1.41", |
|
doi = "10.18653/v1/2023.starsem-1.41", |
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pages = "469--476", |
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} |
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``` |
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|