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--- |
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license: gpl-3.0 |
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language: |
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- en |
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tags: |
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- feature extraction |
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- mobile apps |
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- reviews |
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- token classification |
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- named entity recognition |
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pipeline_tag: token-classification |
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widget: |
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- text: "The share note file feature is completely useless." |
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example_title: "Example 1" |
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- text: "Great app I've tested a lot of free habit tracking apps and this is by far my favorite." |
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example_title: "Example 2" |
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- text: "The only negative feedback I can give about this app is the difficulty level to set a sleep timer on it." |
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example_title: "Example 3" |
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- text: "Does what you want with a small pocket size checklist reminder app" |
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example_title: "Example 4" |
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- text: "Very bad because call recording notification send other person" |
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example_title: "Example 5" |
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- text: "I originally downloaded the app for pomodoro timing, but I stayed for the project management features, with syncing." |
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example_title: "Example 6" |
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- text: "It works accurate and I bought a portable one lap gps tracker it have a great battery Life" |
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example_title: "Example 7" |
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- text: "I'm my phone the notifications of group message are not at a time please check what was the reason behind it because due to this default I loose some opportunity" |
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example_title: "Example 8" |
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- text: "There is no setting for recurring alarms" |
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example_title: "Example 9" |
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--- |
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# T-FREX RoBERTa base model |
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--- |
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Please cite this research as: |
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_Q. Motger, A. Miaschi, F. Dell’Orletta, X. Franch, and J. Marco, ‘T-FREX: A Transformer-based Feature Extraction Method from Mobile App Reviews’, in Proceedings of The IEEE International Conference on Software Analysis, Evolution and Reengineering (SANER), 2024. Pre-print available at: https://arxiv.org/abs/2401.03833_ |
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--- |
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T-FREX is a transformer-based feature extraction method for mobile app reviews based on fine-tuning Large Language Models (LLMs) for a named entity recognition task. We collect a dataset of ground truth features from users in a real crowdsourced software recommendation platform, and we use this dataset to fine-tune multiple LLMs under different data configurations. We assess the performance of T-FREX with respect to this ground truth, and we complement our analysis by comparing T-FREX with a baseline method from the field. Finally, we assess the quality of new features predicted by T-FREX through an external human evaluation. Results show that T-FREX outperforms on average the traditional syntactic-based method, especially when discovering new features from a domain for which the model has been fine-tuned. |
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Source code for data generation, fine-tuning and model inference are available in the original [GitHub repository](https://github.com/gessi-chatbots/t-frex/). |
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## Model description |
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This version of T-FREX has been fine-tuned for [token classification](https://huggingface.co/docs/transformers/tasks/token_classification#train) from [XLNet large model](https://huggingface.co/xlnet-large-cased). |
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## Model variations |
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T-FREX includes a set of released, fine-tuned models which are compared in the original study (pre-print available at http://arxiv.org/abs/2401.03833). |
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- [**t-frex-bert-base-uncased**](https://huggingface.co/quim-motger/t-frex-bert-base-uncased) |
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- [**t-frex-bert-large-uncased**](https://huggingface.co/quim-motger/t-frex-bert-large-uncased) |
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- [**t-frex-roberta-base**](https://huggingface.co/quim-motger/t-frex-roberta-base) |
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- [**t-frex-roberta-large**](https://huggingface.co/quim-motger/t-frex-roberta-large) |
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- [**t-frex-xlnet-base-cased**](https://huggingface.co/quim-motger/t-frex-xlnet-base-cased) |
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- [**t-frex-xlnet-large-cased**](https://huggingface.co/quim-motger/t-frex-xlnet-large-cased) |
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## How to use |
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```python |
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from transformers import AutoTokenizer, AutoModelForTokenClassification, pipeline |
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# Load the pre-trained model and tokenizer |
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model_name = "quim-motger/t-frex-xlnet-large-cased" |
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tokenizer = AutoTokenizer.from_pretrained(model_name) |
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model = AutoModelForTokenClassification.from_pretrained(model_name) |
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# Create a pipeline for named entity recognition |
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ner_pipeline = pipeline("ner", model=model, tokenizer=tokenizer) |
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# Example text |
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text = "The share note file feature is completely useless." |
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# Perform named entity recognition |
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entities = ner_pipeline(text) |
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# Print the recognized entities |
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for entity in entities: |
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print(f"Entity: {entity['word']}, Label: {entity['entity']}, Score: {entity['score']:.4f}") |
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# Example with multiple texts |
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texts = [ |
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"Great app I've tested a lot of free habit tracking apps and this is by far my favorite.", |
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"The only negative feedback I can give about this app is the difficulty level to set a sleep timer on it." |
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] |
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# Perform named entity recognition on multiple texts |
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for text in texts: |
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entities = ner_pipeline(text) |
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print(f"Text: {text}") |
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for entity in entities: |
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print(f" Entity: {entity['word']}, Label: {entity['entity']}, Score: {entity['score']:.4f}") |
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``` |