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metadata
license: apache-2.0
language: en
datasets:
  - Jzuluaga/atco2_corpus_1h
tags:
  - text
  - token-classification
  - en-atc
  - en
  - generated_from_trainer
  - bert
  - ner-for-atc
metrics:
  - Precision
  - Recall
  - Accuracy
  - F1
widget:
  - text: >-
      csa two nine six startup approved mike current qnh one zero one eight time
      check one seven
  - text: >-
      swiss four eight seven november runway three one cleared for takeoff wind
      one three zero degrees seven knots
  - text: >-
      lufthansa five yankee victor runway one three clear to land wind zero
      seven zero degrees
  - text: austrian seven one zulu hello to you reduce one six zero knots
  - text: >-
      sky travel one nine two approaching holding point three one ready for
      departure
model-index:
  - name: bert-base-ner-atc-en-atco2-1h
    results:
      - task:
          type: token-classification
          name: ner
        dataset:
          type: Jzuluaga/atco2_corpus_1h
          name: ATCO2 corpus (Air Traffic Control Communications)
          config: test
          split: test
        metrics:
          - type: F1
            value: 0.94
            name: TEST F1 (callsign)
            verified: false
          - type: F1
            value: 0.74
            name: TEST F1 (command)
            verified: false
          - type: F1
            value: 0.81
            name: TEST F1 (value)
            verified: false

bert-base-ner-atc-en-atco2-1h

This model allow to perform named-entity recognition (NER) on air traffic control communications data. We solve this challenge by performing token classification (NER) with a BERT model. We fine-tune a pretrained BERT model on the ner task.

For instance, if you have the following transcripts/gold annotations:

  • Utterance: lufthansa three two five cleared to land runway three four left

Could you tell what are the main entities in the communication? The desired output is shown below:

  • Named-entity module output: [call] lufthansa three two five [/call] [cmd] cleared to land [/cmd] [val] runway three four left [/val]

This model is a fine-tuned version of bert-base-uncased on the atco2_corpus_1h.

GitHub

It achieves the following results on the development set:

  • Loss: 1.4282
  • Precision: 0.6195
  • Recall: 0.7071
  • F1: 0.6604
  • Accuracy: 0.8182

Paper: ATCO2 corpus: A Large-Scale Dataset for Research on Automatic Speech Recognition and Natural Language Understanding of Air Traffic Control Communications

Authors: Juan Zuluaga-Gomez, Karel Veselý, Igor Szöke, Petr Motlicek, Martin Kocour, Mickael Rigault, Khalid Choukri, Amrutha Prasad and others

Abstract: Personal assistants, automatic speech recognizers and dialogue understanding systems are becoming more critical in our interconnected digital world. A clear example is air traffic control (ATC) communications. ATC aims at guiding aircraft and controlling the airspace in a safe and optimal manner. These voice-based dialogues are carried between an air traffic controller (ATCO) and pilots via very-high frequency radio channels. In order to incorporate these novel technologies into ATC (low-resource domain), large-scale annotated datasets are required to develop the data-driven AI systems. Two examples are automatic speech recognition (ASR) and natural language understanding (NLU). In this paper, we introduce the ATCO2 corpus, a dataset that aims at fostering research on the challenging ATC field, which has lagged behind due to lack of annotated data. The ATCO2 corpus covers 1) data collection and pre-processing, 2) pseudo-annotations of speech data, and 3) extraction of ATC-related named entities. The ATCO2 corpus is split into three subsets. 1) ATCO2-test-set corpus contains 4 hours of ATC speech with manual transcripts and a subset with gold annotations for named-entity recognition (callsign, command, value). 2) The ATCO2-PL-set corpus consists of 5281 hours of unlabeled ATC data enriched with automatic transcripts from an in-domain speech recognizer, contextual information, speaker turn information, signal-to-noise ratio estimate and English language detection score per sample. Both available for purchase through ELDA at this http URL. 3) The ATCO2-test-set-1h corpus is a one-hour subset from the original test set corpus, that we are offering for free at this url: https://www.atco2.org/data. We expect the ATCO2 corpus will foster research on robust ASR and NLU not only in the field of ATC communications but also in the general research community.

Code — GitHub repository: https://github.com/idiap/atco2-corpus

Intended uses & limitations

This model was fine-tuned on air traffic control data. We don't expect that it keeps the same performance on some others datasets where BERT was pre-trained or fine-tuned.

Training and evaluation data

See Table 6 (page 18) in our paper: ATCO2 corpus: A Large-Scale Dataset for Research on Automatic Speech Recognition and Natural Language Understanding of Air Traffic Control Communications. We described there the data used to fine-tune our NER model.

Writing your own inference script

The snippet of code:

from transformers import pipeline, AutoTokenizer, AutoModelForTokenClassification

tokenizer = AutoTokenizer.from_pretrained("Jzuluaga/bert-base-ner-atc-en-atco2-1h")
model = AutoModelForTokenClassification.from_pretrained("Jzuluaga/bert-base-ner-atc-en-atco2-1h")


##### Process text sample
from transformers import pipeline

nlp = pipeline('ner', model=model, tokenizer=tokenizer, aggregation_strategy="first")
nlp("lufthansa three two five cleared to land runway three four left")

# output:
[{'entity_group': 'callsign', 'score': 0.8753265, 
'word': 'lufthansa three two five', 
'start': 0, 'end': 24},
{'entity_group': 'command', 'score': 0.99988264, 
'word': 'cleared to land', 'start': 25, 'end': 40}, 
{'entity_group': 'value', 'score': 0.9999145, 
'word': 'runway three four left', 'start': 41, 'end': 63}]

Cite us

If you use this code for your research, please cite our paper with:

@article{zuluaga2022bertraffic,
  title={BERTraffic: BERT-based Joint Speaker Role and Speaker Change Detection for Air Traffic Control Communications},
  author={Zuluaga-Gomez, Juan and Sarfjoo, Seyyed Saeed and Prasad, Amrutha and others},
  journal={IEEE Spoken Language Technology Workshop (SLT), Doha, Qatar},
  year={2022}
  }

and,

@article{zuluaga2022how,
    title={How Does Pre-trained Wav2Vec2. 0 Perform on Domain Shifted ASR? An Extensive Benchmark on Air Traffic Control Communications},
    author={Zuluaga-Gomez, Juan and Prasad, Amrutha and Nigmatulina, Iuliia and Sarfjoo, Saeed and others},
    journal={IEEE Spoken Language Technology Workshop (SLT), Doha, Qatar},
    year={2022}
  }

and,

@article{zuluaga2022atco2,
  title={ATCO2 corpus: A Large-Scale Dataset for Research on Automatic Speech Recognition and Natural Language Understanding of Air Traffic Control Communications},
  author={Zuluaga-Gomez, Juan and Vesel{\`y}, Karel and Sz{\"o}ke, Igor and Motlicek, Petr and others},
  journal={arXiv preprint arXiv:2211.04054},
  year={2022}
}

Training procedure

Training hyperparameters

The following hyperparameters were used during training:

  • learning_rate: 5e-05
  • train_batch_size: 32
  • eval_batch_size: 16
  • seed: 42
  • gradient_accumulation_steps: 2
  • total_train_batch_size: 64
  • optimizer: Adam with betas=(0.9,0.999) and epsilon=1e-08
  • lr_scheduler_type: linear
  • lr_scheduler_warmup_steps: 500
  • training_steps: 3000

Training results

Training Loss Epoch Step Validation Loss Precision Recall F1 Accuracy
No log 125.0 500 0.8692 0.6396 0.7172 0.6762 0.8307
0.2158 250.0 1000 1.0074 0.5702 0.6970 0.6273 0.8245
0.2158 375.0 1500 1.3560 0.6577 0.7374 0.6952 0.8119
0.0184 500.0 2000 1.3393 0.6182 0.6869 0.6507 0.8056
0.0184 625.0 2500 1.3528 0.6087 0.7071 0.6542 0.8213
0.0175 750.0 3000 1.4282 0.6195 0.7071 0.6604 0.8182

Framework versions

  • Transformers 4.24.0
  • Pytorch 1.13.0+cu117
  • Datasets 2.7.0
  • Tokenizers 0.13.2