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<img src="./fig/bot.png" width="150" class="left"><img src="./fig/logo.png" width="500" class="center">

Authors: Weizhe Yuan, Pengfei Liu, Graham Neubig

Updates

2021-10-22 Updated extractor.<br> 2021-3-11 Updated tagger.<br>

Outline

Motivation

Demo

(The Demo is currently offline due to computational consideration. We will re-start it once the computational resource is sufficient.)

Have a TRY

Dataset

(The dataset is under Apache-2.0 license)

To download our dataset, run

sh download_dataset.sh

There will be a dataset folder that contains the data. Please read the README.md in dataset folder to know more about the details.

To use our trained tagger, run

sh download_tagger.sh

There will be a seqlab_final folder that contains our trained tagger. Move it into the tagger folder in this repo. The detailed usage of our tagger can be refered here.

Evaluation

We first define two high-level objectives of scientific peer review following Jefferson et al. (2002a). and Smith (2006).

  1. Selecting high-quality submissions for publication.
  2. Improving different aspects of a paper by providing detailed comments.

We then make the first step towards review evaluation for scientific papers by proposing seven quantifiable metrics that can characterize a review from multiple perspectives. The evaluation metrics are shown in Fig.1, red represents absolute metric and blue represents relative metric.

<img src="./fig/eval_metrics.png" width="500" class="center">

Model

We decompose review generation into two steps, and consider using a extract-then-generate paradigm.

We consider three extraction strategies, which can be visualized in Fig.2.

  1. Section-based Extraction
  2. Cross-entropy Method Extraction (see extractor folder for details)
  3. Hybrid Extraction
<img src="./fig/extract.png" width="350" class="center">

We consider two generation frameworks, which can be visualized in Fig.3.

  1. Vanilla Sequence to Sequence
  2. Jointly Sequence to Sequence and Sequence Labeling
<img src="./fig/generation.png" width="500" class="center">

Bias

To characterize potential bias existing in reviews, we define aspect score as the percentage of positive occurrences with respect to each review's aspects.

Absolute bias

Absolute bias can be visualized directly by plotting the aspect scores of different groups w.r.t each aspect. An example is shown in Fig.4.

<img src="./fig/spider_bias.png" width="800" class="center">

Relative bias

Relative bias quantifies the relative favor for certain groups between human reviewers and system reviewers. And we define a metric called disparity difference to measure relative bias. The calculation of disparity difference can be visualized in Fig.5.

<img src="./fig/disparity_diff.png" width="800" class="center">

Challenges

We summarize eight challenges in the pursuit of a good review generation system.

  1. Model
    • Long Document Modeling
    • Pre-trained Model for Scientific Domain
    • Structure Information
    • External Knowledge
  2. Dataset
    • More Open, Fine-grained Review Data
    • More Accurate and Powerful Scientific Paper Parser
  3. Evaluation
    • Fairness and Bias in Generated Text
    • Reliability

Acknowledgement

This work cannot be accomplished without the help of many researchers.

We would like to thank people for their generous support, especially, Gábor Berend, Zhouhan Lin, William W. Cohen, Pengcheng Yin, Tiange Luo, Yuki M. Asano, Junjie Yan, Tuomas Haarnoja, Dandan Guo, Jie Fu, Lei Chen, Jinlan Fu, Jiapeng Wu, Yiran Chen, Wenshan Wang, Ziyi Dou, Yixin Liu, Junxian He, Bahetiyaer Bare, Saizheng Zhang, Jiateng Xie, Spyros Gidaris, Marco Federici, Junji Dai, Zihuiwen Ye, Jie Zhou, Yufang Liu, Yue Zhang, Ruifeng Xu, Zhenghua Li, Chunting Zhou, Yang Wei, Jiahao Wang, Bowen Tan, Anda Zhou.

Bib

@misc{yuan2021automate,
      title={Can We Automate Scientific Reviewing?}, 
      author={Weizhe Yuan and Pengfei Liu and Graham Neubig},
      year={2021},
      eprint={2102.00176},
      archivePrefix={arXiv},
      primaryClass={cs.CL}
}