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--- |
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inference: |
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parameters: |
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do_sample: true |
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max_length: 512 |
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top_p: 0.9 |
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repetition_penalty: 1.0 |
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language: |
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- en |
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license: mit |
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metrics: |
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- sacrebleu |
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- bert_score |
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- rouge |
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- meteor |
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- sari |
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- ari |
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- "Automated Readability Index" |
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tags: |
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- "text2text generation" |
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task: |
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name: "scientific abstract simplification" |
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type: "text2text generation" |
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widget: |
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- |
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text: "summarize, simplify, and contextualize: The COVID-19 pandemic presented enormous data challenges in the United States. Policy makers, epidemiological modelers, and health researchers all require up-to-date data on the pandemic and relevant public behavior, ideally at fine spatial and temporal resolution. The COVIDcast API is our attempt to fill this need: Operational since April 2020, it provides open access to both traditional public health surveillance signals (cases, deaths, and hospitalizations) and many auxiliary indicators of COVID-19 activity, such as signals extracted from deidentified medical claims data, massive online surveys, cell phone mobility data, and internet search trends. These are available at a fine geographic resolution (mostly at the county level) and are updated daily. The COVIDcast API also tracks all revisions to historical data, allowing modelers to account for the frequent revisions and backfill that are common for many public health data sources. All of the data are available in a common format through the API and accompanying R and Python software packages. This paper describes the data sources and signals, and provides examples demonstrating that the auxiliary signals in the COVIDcast API present information relevant to tracking COVID activity, augmenting traditional public health reporting and empowering research and decision-making." |
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example_title: "covid-api paper, from PNAS" |
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- |
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text: "summarize, simplify, and contextualize: Potato mop-top virus (PMTV) is considered an emerging threat to potato production in the United States. PMTV is transmitted by a soil-borne protist, Spongospora subterranean. Rapid, accurate, and sensitive detection of PMTV in leaves and tubers is an essential component in PMTV management program. A rapid test that can be adapted to in-field, on-site testing with minimal sample manipulation could help in ensuring the sanitary status of the produce in situations such as certification programs and shipping point inspections. Toward that goal, a rapid and highly sensitive recombinase polymerase amplification (RPA)-based test was developed for PMTV detection in potato tubers. The test combines the convenience of RPA assay with a simple sample extraction procedure, making it amenable to rapid on-site diagnosis of PMTV. Furthermore, the assay was duplexed with a plant internal control to monitor sample extraction and RPA reaction performance. The method described could detect as little as 10 fg of PMTV RNA transcript in various potato tissues, the diagnostic limit of detection (LOQ) similar to that of traditional molecular methods." |
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example_title: "potato paper, from PLOS ONE" |
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text: "summarize, simplify, and contextualize: One of the most thrilling cultural experiences is to hear live symphony-orchestra music build up from a whispering passage to a monumental fortissimo. The impact of such a crescendo has been thought to depend only on the musicians’ skill, but here we show that interactions between the concert-hall acoustics and listeners’ hearing also play a major role in musical dynamics. These interactions contribute to the shoebox-type concert hall’s established success, but little prior research has been devoted to dynamic expression in this three-part transmission chain as a complete system. More forceful orchestral playing disproportionately excites high frequency harmonics more than those near the note’s fundamental. This effect results in not only more sound energy, but also a different tone color. The concert hall transmits this sound, and the room geometry defines from which directions acoustic reflections arrive at the listener. Binaural directional hearing emphasizes high frequencies more when sound arrives from the sides of the head rather than from the median plane. Simultaneously, these same frequencies are emphasized by higher orchestral-playing dynamics. When the room geometry provides reflections from these directions, the perceived dynamic range is enhanced. Current room-acoustic evaluation methods assume linear behavior and thus neglect this effect. The hypothesis presented here is that the auditory excitation by reflections is emphasized with an orchestra forte most in concert halls with strong lateral reflections. The enhanced dynamic range provides an explanation for the success of rectangularly shaped concert-hall geometry." |
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example_title: "music paper, from PNAS" |
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- |
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text: "summarize, simplify, and contextualize: Children in industrialized cultures typically succeed on Give-N, a test of counting ability, by age 4. On the other hand, counting appears to be learned much later in the Tsimane’, an indigenous group in the Bolivian Amazon. This study tests three hypotheses for what may cause this difference in timing: (a) Tsimane’ children may be shy in providing behavioral responses to number tasks, (b) Tsimane’ children may not memorize the verbal list of number words early in acquisition, and/or (c) home environments may not support mathematical learning in the same way as in US samples, leading Tsimane’ children to primarily acquire mathematics through formalized schooling. Our results suggest that most of our subjects are not inhibited by shyness in responding to experimental tasks. We also find that Tsimane’ children (N = 100, ages 4-11) learn the verbal list later than US children, but even upon acquiring this list, still take time to pass Give-N tasks. We find that performance in counting varies across tasks and is related to formal schooling. These results highlight the importance of formal education, including instruction in the count list, in learning the meanings of the number words." |
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example_title: "given-n paper, from PLOS ONE" |
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--- |
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# TL;DR |
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Scientific Abstract Simplification (SAS) is a tool that rewrites difficult-to-understand scientific abstracts into simpler, easier-to-read versions. |
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Our goal is to make scientific knowledge more accessible to everyone. If you've already tried our baseline model (`sas_baseline`), |
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the current model is even better on all evaluation metrics. You can try it now with the Hosted Inference API on the right. |
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Simply choose one of the provided examples or enter your own scientific abstract. |
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Just remember to include the instruction "summarize, simplify, and contextualize: " at the beginning (with a space after the colon). |
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For local use, see the [Usage](#Usage) section. |
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# Project Description |
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"Open science has greatly reduced the barriers to accessing scientific papers. However, reachable research does not mean accessible knowledge. |
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As a result, many people may prefer to trust short stories on social media rather than attempting to read a scientific paper. |
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This is understandable, as we humans often prefer stories to dry, technical information. |
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So, why not "translate" these complex scientific abstracts into simpler, more accessible stories? Some prestigious journals are already taking steps towards greater accessibility. |
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For example, PNAS requires authors to submit Significance Statements that can be understood by an "undergraduate-educated scientist," and Science includes an editor abstract for a quick overview of the paper's key points. |
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In this project, we aim to use AI to rewrite scientific abstracts as easily understandable scientific stories. |
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To do this, we have created two new datasets: one containing PNAS abstract-significance pairs, and the other containing editor abstracts from Science. |
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We use a Transformer model (a variant called Flan-T5) to fine-tune our model for the task of simplifying scientific abstracts. Initially, the model will be fine-tuned using multiple discrete instructions by combining four relevant tasks in a challenge-proportional manner (i.e., we call it Multi-Instruction Pretuning). |
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Then, we continue fine-tuning the model using only the abstract-significance corpus. Our model is able to produce lay summaries that are better than models fine-tuned only with the abstract-significance corpus and models fine-tuned with task combinations in traditional ways. |
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We hope our work can facilitate greater understanding of scientific research and allow more people to benefit from open science. |
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- **Model type:** Language model |
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- **Developed by:** |
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- PIs: Jason Clark and Hannah McKelvey, Montana State University |
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- Fellow: Haining Wang, Indiana University Bloomington; Deanna Zarrillo, Drexel University |
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- Collaborator: Zuoyu Tian, Indiana University Bloomington |
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- [LEADING](https://cci.drexel.edu/mrc/leading/) Montana State University Library, Project "TL;DR it": Automating Article Synopses for Search Engine Optimization and Citizen Science |
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- **Language(s) (NLP):** English |
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- **License:** MIT |
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- **Parent Model:** [FLAN-T5-large](https://huggingface.co/google/flan-t5-large) |
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# Usage |
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Use the code below to get started with the model. Remember to prepend the `INSTRUCTION` for best performance. |
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```python |
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import torch |
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from transformers import AutoTokenizer, AutoModelForSeq2SeqLM |
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INSTRUCTION = "summarize, simplify, and contextualize: " |
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tokenizer = AutoTokenizer.from_pretrained("haining/scientific_abstract_simplification") |
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model = AutoModelForSeq2SeqLM.from_pretrained("haining/scientific_abstract_simplification") |
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input_text = "The COVID-19 pandemic presented enormous data challenges in the United States. Policy makers, epidemiological modelers, and health researchers all require up-to-date data on the pandemic and relevant public behavior, ideally at fine spatial and temporal resolution. The COVIDcast API is our attempt to fill this need: Operational since April 2020, it provides open access to both traditional public health surveillance signals (cases, deaths, and hospitalizations) and many auxiliary indicators of COVID-19 activity, such as signals extracted from deidentified medical claims data, massive online surveys, cell phone mobility data, and internet search trends. These are available at a fine geographic resolution (mostly at the county level) and are updated daily. The COVIDcast API also tracks all revisions to historical data, allowing modelers to account for the frequent revisions and backfill that are common for many public health data sources. All of the data are available in a common format through the API and accompanying R and Python software packages. This paper describes the data sources and signals, and provides examples demonstrating that the auxiliary signals in the COVIDcast API present information relevant to tracking COVID activity, augmenting traditional public health reporting and empowering research and decision-making." |
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encoding = tokenizer(INSTRUCTION + input_text, |
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max_length=672, |
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padding='max_length', |
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truncation=True, |
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return_tensors='pt') |
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decoded_ids = model.generate(input_ids=encoding['input_ids'], |
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attention_mask=encoding['attention_mask'], |
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max_length=512, |
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top_p=.9, |
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do_sample=True) |
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print(tokenizer.decode(decoded_ids[0], skip_special_tokens=True)) |
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``` |
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# Training |
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## Data |
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| Corpus | # Training/Dev/Test Samples | # Training Tokens (source, target) | # Validation Tokens (source, target) | # Test Tokens (source, target) | Note | |
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|----------------------------------|-----------------------------|------------------------------------|--------------------------------------|--------------------------------|----------------------------------------------------------------------------------------------------------------------------------------| |
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| Scientific Abstract-Significance | 3,030/200/200 | 707,071, 375,433 | 45,697, 24,901 | 46,985, 24,426 | - | |
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| Editor Abstract | 732/91/92 | 154,808, 194,721 | 19,675, 24,421 | 19,539, 24,332 | - | |
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| Wiki Auto | 28,364/1,000/1,000 | 18,239,990, 12,547,272 | 643,157, 444,034 | 642549, 444,883 | We used the ACL version, adopted from Huggingface datasets. The validation and test samples are split from the corpus and kept frozen. | |
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| CNN/DailyMail | 287,113/13,368/11,490 | - | - | - | We used the 2.0 version, adopted from Huggingface datasets. | |
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## Setup |
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We finetuned the base model (flan-t5-large) on multiple relevant tasks with standard language modeling loss. During training, the source text of each task is prepended with an task-specific instruction and mapped to the corresponding target text. For example, "simplify: " is added before a wiki text, and the whole text is fed into the model to line up with the corresponding simple wiki text. The tuning process has two steps. |
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| Task | Corpus | Instruction | Optimal samples | |
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|------------------------------------|----------------------------------|--------------------------------------------|-----------------| |
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| Scientific Abstract Simplification | Scientific Abstract-Significance | "summarize, simplify, and contextualize: " | 39,200 | |
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| Recontextualization | Editor Abstract | "contextualize: " | 2,200 | |
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| Simplification | Wiki Auto | "simplify: " | 57,000 | |
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| Summarization | CNN/DailyMail | "summarize: " | 165,000 | |
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| Total | Challenge-proportional Mixing | n/a | 263,400 | |
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- Multi-instruction pretuning: In the stage, we first created a task mixture using "challenge-proportional mixing" method. In a seperate pilot studie, for each task, we finetuned it on a base model and observed the number of samples when validation loss starts to rise. We mixed the samples of each task proportional to its optimal number of samples. A corpus is exhausted before upsampling if the number of total samples is smaller than its optimal number. We finetune with the task mixture (263,400 samples) with the aforementioned template. |
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- fine-tuning: In this stage, we continued finetuning the checkpoint solely with the Scientific Abstract-Significance corpus till optimal validation loss was observed. |
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The multi-instruction tuning and the retuning took roughly 63 hours and 8 hours, respectively, on two NVIDIA RTX A5000 (24GB memory each) GPUs. We saved the checkpoint with the lowest validation loss for inference. We used the AdamW optimizer and a learning rate of 3e-5 with fully sharded data parallel strategy across training stages. The batch size equals to 1. |
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# Evaluation |
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The model is evaluated on the SAS test set using SacreBLEU, METEOR, BERTScore, ROUGLE, SARI, and ARI. |
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## Metrics |
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<details> |
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<summary> Click to expand </summary> |
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- [SacreBLEU](https://huggingface.co/spaces/evaluate-metric/sacrebleu): SacreBLEU provides hassle-free computation of shareable, comparable, and reproducible BLEU scores. Inspired by Rico Sennrich’s multi-bleu-detok.perl, it produces the official WMT scores but works with plain text. It also knows all the standard test sets and handles downloading, processing, and tokenization for you. |
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- [BERTScore](https://huggingface.co/spaces/evaluate-metric/bertscore): BERTScore leverages the pre-trained contextual embeddings from BERT and matches words in candidate and reference sentences by cosine similarity. It has been shown to correlate with human judgment on sentence-level and system-level evaluation. Moreover, BERTScore computes precision, recall, and F1 measure, which can be useful for evaluating different language generation tasks. |
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- [ROUGLE](https://huggingface.co/spaces/evaluate-metric/rouge)-1/2/L: ROUGE is a set of metrics and a software package used for evaluating automatic summarization and machine translation software in natural language processing. The metrics compare an automatically produced summary or translation against a reference or a set of references (human-produced) summary or translation. |
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- [METEOR](https://huggingface.co/spaces/evaluate-metric/meteor): METEOR, an automatic metric for machine translation evaluation that is based on a generalized concept of unigram matching between the machine-produced translation and human-produced reference translations. Unigrams can be matched based on their surface forms, stemmed forms, and meanings; furthermore, METEOR can be easily extended to include more advanced matching strategies. Once all generalized unigram matches between the two strings have been found, METEOR computes a score for this matching using a combination of unigram-precision, unigram-recall, and a measure of fragmentation that is designed to directly capture how well-ordered the matched words in the machine translation are in relation to the reference. |
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- [SARI](https://huggingface.co/spaces/evaluate-metric/sari): SARI is a metric used for evaluating automatic text simplification systems. The metric compares the predicted simplified sentences against the reference and the source sentences. It explicitly measures the goodness of words that are added, deleted and kept by the system. Sari = (F1_add + F1_keep + P_del) / 3 where F1_add: n-gram F1 score for add operation F1_keep: n-gram F1 score for keep operation P_del: n-gram precision score for delete operation n = 4, as in the original paper. |
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- [The Automated Readability Index (ARI)](https://www.readabilityformulas.com/automated-readability-index.php): ARI is a readability test designed to assess the understandability of a text. Like other popular readability formulas, the ARI formula outputs a number which approximates the grade level needed to comprehend the text. For example, if the ARI outputs the number 10, this equates to a high school student, ages 15-16 years old; a number 3 means students in 3rd grade (ages 8-9 yrs. old) should be able to comprehend the text. |
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</details> |
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Implementations of SacreBLEU, BERT Score, ROUGLE, METEOR, and SARI are from Huggingface [`evaluate`](https://pypi.org/project/evaluate/) v.0.3.0. ARI is from [`py-readability-metrics`](https://pypi.org/project/py-readability-metrics/) v.1.4.5. |
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## Results |
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We tested our model on the SAS test set (200 samples). We generate 10 lay summaries based on each sample's abstract. During generation, we used top-p sampling with p=0.9. The mean performance is reported below. |
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| Metrics | SAS | |
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|----------------|---------| |
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| SacreBLEU↑ | 25.60 | |
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| BERT Score F1↑ | 90.14 | |
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| ROUGLE-1↑ | 52.28 | |
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| ROUGLE-2↑ | 29.61 | |
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| ROUGLE-L↑ | 38.02 | |
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| METEOR↑ | 43.75 | |
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| SARI↑ | 51.96 | |
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| ARI↓ | 17.04 | |
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Note: 1. Some generated texts are too short (less than 100 words) to calcualte meaningful ARI. We therefore concatenated adjecent five texts and compute ARI for the 400 longer texts (instead of original 2,000 texts). 2. BERT score, ROUGE, and METEOR are multiplied by 100. |
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# Contact |
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Please [contact us](mailto:hw56@indiana.edu) for any questions or suggestions. |
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# Disclaimer |
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This model is designed to make scientific abstracts more accessible. Its outputs should not be relied upon for any purpose outside of this scope. There is no guarantee that the generated text accurately reflects the research it is based on. When making important decisions, it is recommended to seek the advice of human experts or consult the original papers. |
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# Acknowledgement |
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This research is supported by the Institute of Museum and Library Services (IMLS) RE-246450-OLS-20. |