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metadata
language:
  - pt
tags:
  - generated_from_trainer
datasets:
  - lener_br
metrics:
  - precision
  - recall
  - f1
  - accuracy
model-index:
  - name: checkpoints
    results:
      - task:
          name: Token Classification
          type: token-classification
        dataset:
          name: lener_br
          type: lener_br
        metrics:
          - name: F1
            type: f1
            value: 0.9082022949426265
          - name: Precision
            type: precision
            value: 0.8975220495590088
          - name: Recall
            type: recall
            value: 0.9191397849462366
          - name: Accuracy
            type: accuracy
            value: 0.9808310603867311
          - name: Loss
            type: loss
            value: 0.1228889599442482
widget:
  - text: >-
      Ao Instituto Médico Legal da jurisdição do acidente ou da residência
      cumpre fornecer, no prazo de 90 dias, laudo à vítima (art. 5, § 5, Lei n.
      6.194/74  de 19 de dezembro de 1974), função técnica que pode ser suprida
      por prova pericial realizada por ordem do juízo da causa, ou por prova
      técnica realizada no âmbito administrativo que se mostre coerente com os
      demais elementos de prova constante dos autos.
  - text: >-
      Acrescento que não há de se falar em violação do artigo 114, § 3º, da
      Constituição Federal, posto que referido dispositivo revela-se
      impertinente, tratando da possibilidade de ajuizamento de dissídio
      coletivo pelo Ministério Público do Trabalho nos casos de greve em
      atividade essencial.
  - text: >-
      Todavia, entendo que extrair da aludida norma o sentido expresso na
      redação acima implica desconstruir o significado do texto constitucional,
      o que é absolutamente vedado ao intérprete. Nesse sentido, cito Dimitri
      Dimoulis: ‘(...) ao intérprete não é dado escolher significados que não
      estejam abarcados pela moldura da norma. Interpretar não pode significar
      violentar a norma.’ (Positivismo Jurídico. São Paulo: Método, 2006, p.
      220).59. Dessa forma, deve-se tomar o sentido etimológico como limite da
      atividade interpretativa, a qual não pode superado, a ponto de destruir a
      própria norma a ser interpretada. Ou, como diz Konrad Hesse, ‘o texto da
      norma é o limite insuperável da atividade interpretativa.’ (Elementos de
      Direito Constitucional da República Federal da Alemanha, Porto Alegre:
      Sergio Antonio Fabris, 2003, p. 71).

(BERT large) NER model in the legal domain in Portuguese (LeNER-Br)

ner-bert-large-portuguese-cased-lenerbr is a NER model (token classification) in the legal domain in Portuguese that was finetuned on 20/12/2021 in Google Colab from the model pierreguillou/bert-large-cased-pt-lenerbr on the dataset LeNER_br by using a NER objective.

Due to the small size of the finetuning dataset, the model overfitted before to reach the end of training. Here are the overall final metrics on the validation dataset (note: see the paragraph "Validation metrics by Named Entity" to get detailed metrics):

  • f1: 0.9082022949426265
  • precision: 0.8975220495590088
  • recall: 0.9191397849462366
  • accuracy: 0.9808310603867311
  • loss: 0.1228889599442482

Check as well the base version of this model with a f1 of 0.893.

Note: the model pierreguillou/bert-large-cased-pt-lenerbr is a language model that was created through the finetuning of the model BERTimbau large on the dataset LeNER-Br language modeling by using a MASK objective. This first specialization of the language model before finetuning on the NER task allows to get a better NER model.

Blog post

NLP | Modelos e Web App para Reconhecimento de Entidade Nomeada (NER) no domínio jurídico brasileiro (29/12/2021)

Widget & App

You can test this model into the widget of this page.

Use as well the NER App that allows comparing the 2 BERT models (base and large) fitted in the NER task with the legal LeNER-Br dataset.

Using the model for inference in production

# install pytorch: check https://pytorch.org/
# !pip install transformers 
from transformers import AutoModelForTokenClassification, AutoTokenizer
import torch

# parameters
model_name = "pierreguillou/ner-bert-large-cased-pt-lenerbr"
model = AutoModelForTokenClassification.from_pretrained(model_name)
tokenizer = AutoTokenizer.from_pretrained(model_name)

input_text = "Acrescento que não há de se falar em violação do artigo 114, § 3º, da Constituição Federal, posto que referido dispositivo revela-se impertinente, tratando da possibilidade de ajuizamento de dissídio coletivo pelo Ministério Público do Trabalho nos casos de greve em atividade essencial."

# tokenization
inputs = tokenizer(input_text, max_length=512, truncation=True, return_tensors="pt")
tokens = inputs.tokens()

# get predictions
outputs = model(**inputs).logits
predictions = torch.argmax(outputs, dim=2)

# print predictions
for token, prediction in zip(tokens, predictions[0].numpy()):
    print((token, model.config.id2label[prediction]))

You can use pipeline, too. However, it seems to have an issue regarding to the max_length of the input sequence.

!pip install transformers
import transformers
from transformers import pipeline

model_name = "pierreguillou/ner-bert-large-cased-pt-lenerbr"

ner = pipeline(
    "ner",
    model=model_name
) 

ner(input_text)

Training procedure

Notebook

The notebook of finetuning (HuggingFace_Notebook_token_classification_NER_LeNER_Br.ipynb) is in github.

Hyperparameters

batch, learning rate...

  • per_device_batch_size = 2
  • gradient_accumulation_steps = 2
  • learning_rate = 2e-5
  • num_train_epochs = 10
  • weight_decay = 0.01
  • optimizer = AdamW
  • betas = (0.9,0.999)
  • epsilon = 1e-08
  • lr_scheduler_type = linear
  • seed = 42

save model & load best model

  • save_total_limit = 7
  • logging_steps = 500
  • eval_steps = logging_steps
  • evaluation_strategy = 'steps'
  • logging_strategy = 'steps'
  • save_strategy = 'steps'
  • save_steps = logging_steps
  • load_best_model_at_end = True
  • fp16 = True

get best model through a metric

  • metric_for_best_model = 'eval_f1'
  • greater_is_better = True

Training results

Num examples = 7828
Num Epochs = 20
Instantaneous batch size per device = 2
Total train batch size (w. parallel, distributed & accumulation) = 4
Gradient Accumulation steps = 2
Total optimization steps = 39140

Step   Training Loss  Validation Loss  Precision  Recall    F1        Accuracy
500    0.250000       0.140582         0.760833   0.770323  0.765548  0.963125
1000   0.076200       0.117882         0.829082   0.817849  0.823428  0.966569
1500   0.082400       0.150047         0.679610   0.914624  0.779795  0.957213
2000   0.047500       0.133443         0.817678   0.857419  0.837077  0.969190
2500   0.034200       0.230139         0.895672   0.845591  0.869912  0.964070
3000   0.033800       0.108022         0.859225   0.887312  0.873043  0.973700
3500   0.030100       0.113467         0.855747   0.885376  0.870310  0.975879
4000   0.029900       0.118619         0.850207   0.884946  0.867229  0.974477
4500   0.022500       0.124327         0.841048   0.890968  0.865288  0.975041
5000   0.020200       0.129294         0.801538   0.918925  0.856227  0.968077
5500   0.019700       0.128344         0.814222   0.908602  0.858827  0.969250
6000   0.024600       0.182563         0.908087   0.866882  0.887006  0.968565
6500   0.012600       0.159217         0.829883   0.913763  0.869806  0.969357
7000   0.020600       0.183726         0.854557   0.893333  0.873515  0.966447
7500   0.014400       0.141395         0.777716   0.905161  0.836613  0.966828
8000   0.013400       0.139378         0.873042   0.899140  0.885899  0.975772
8500   0.014700       0.142521         0.864152   0.901505  0.882433  0.976366

9000   0.010900       0.122889         0.897522   0.919140  0.908202  0.980831

9500   0.013500       0.143407         0.816580   0.906667  0.859268  0.973395
10000  0.010400       0.144946         0.835608   0.908387  0.870479  0.974629
10500  0.007800       0.143086         0.847587   0.910108  0.877735  0.975985
11000  0.008200       0.156379         0.873778   0.884301  0.879008  0.976321
11500  0.008200       0.133356         0.901193   0.910108  0.905628  0.980328
12000  0.006900       0.133476         0.892202   0.920215  0.905992  0.980572
12500  0.006900       0.129991         0.890159   0.904516  0.897280  0.978683

Validation metrics by Named Entity

{'JURISPRUDENCIA': {'f1': 0.8135593220338984,
  'number': 657,
  'precision': 0.865979381443299,
  'recall': 0.7671232876712328},
 'LEGISLACAO': {'f1': 0.8888888888888888,
  'number': 571,
  'precision': 0.8952042628774423,
  'recall': 0.882661996497373},
 'LOCAL': {'f1': 0.850467289719626,
  'number': 194,
  'precision': 0.7777777777777778,
  'recall': 0.9381443298969072},
 'ORGANIZACAO': {'f1': 0.8740635033892258,
  'number': 1340,
  'precision': 0.8373205741626795,
  'recall': 0.914179104477612},
 'PESSOA': {'f1': 0.9836677554829678,
  'number': 1072,
  'precision': 0.9841269841269841,
  'recall': 0.9832089552238806},
 'TEMPO': {'f1': 0.9669669669669669,
  'number': 816,
  'precision': 0.9481743227326266,
  'recall': 0.9865196078431373},
 'overall_accuracy': 0.9808310603867311,
 'overall_f1': 0.9082022949426265,
 'overall_precision': 0.8975220495590088,
 'overall_recall': 0.9191397849462366}