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Implementation of a deep learning model (BiLSTM) to detect code-switching

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PyTorch-Detect-Code-Switching

Task Description

Currently, the research in NLP has been focusing on dealing with types of multilingual content. Thus, the first thing that we need to learn for working on different NLP tasks, such as Question Answering, is to identify the languages accurately on texts. This repository uses the idea behind the paper A Neural Model for Language Identification in Code-Switched Tweets.

Data

http://www.care4lang.seas.gwu.edu/cs2/call.html

This data is a collection of tweets; in particular,three files for the training set and three for the validation set:

  • offsets_mod.tsv:
tweet_id, user_id, start, end, gold label
  • tweets.tsv:
tweet_id, user_id, tweet text
  • data.tsv:
tweet_id, user_id, start, end, token, gold label

The gold labels can be one of three:

  • en
  • es
  • other

Data Analysis

  • As it can be seen in the following table, data are imbalanced in both the training and test set. While the number of English tokens in training data is about 50%, the number of Spanish tokens prevails in the test set.

    label train dev
    en 46042 3028
    es 25563 4185
    other 20257 2370
    sum 91862 9583
  • The number of tweets in the training set is 7400 and in the test set is 832. The tweets in both sets are wholly from two disjoint groups. The training set includes tweets of 6 persons and the test set has 8 persons' tweets.

    user id train dev
    1 1160520883 156036283
    2 1520815188 21327323
    3 1651154684 270181505
    4 169403434 28261811
    5 304724626 364263613
    6 336199483 382890691
    7 418322879
    8 76523773
  • distribution of unique tokens and characters.

    unique token unique token (lower case) unique characters
    train 14366 12220 50
    dev 2771 2559 28
  • The distribution of the length of the tokens are depicted below which are taken by the following one-liner linux command:

    cut -f5 train_data.tsv|awk '{print length}'|sort -n |uniq -c|awk -F" " '{print $NF" " $(NF-1)}'|R --slave -e 'x <- scan(file="stdin", quiet=TRUE,  what=list(numeric(), numeric())); png("Histogram of tokens length-train.png");plot(x[[1]],x[[2]], xlab="length", ylab="frequency", main="Train");'
    token length distribution in training set token length distribution in dev set

    It is evident that both data sets have the same distribution of tokens' lengths with a slight shift. There are several outliers in both datasets as users tend to repeat the characters on social media. The weighted average tokens' lengths for the training and test sets are 3.93 and 4.11, respectively. I've used the following to compute these numbers:

    cut -f5 train_data.tsv|awk '{print length}'|sort -n |uniq -c|awk -F" " '{print $NF" " $(NF-1)}'|tr " " "*"|paste -sd+|bc -l

Preprocssing

  • Some rows in [train|dev]_data.csv include " resulting weird issue with pandas.read_csv. Actually, it reads the next lines till reaches another ", so I set quotechar option to '\0'(=NULL) in pandas.read_csv to solve this issue.
  • I've also checked the availability of the Null in those files with the following command:
    grep -Pa '\x00' data/train_data.tsv
    grep -Pa '\x00' data/dev_data.tsv
  • Another solution to the previous issue is the quoting option with 3 as its value which means QUOTE_NONE.
  • As it is mentioned in the paper, the data contains many long and repetitive character sequences such as “hahahaha...”. To deal with these, we restricted any sequence of repeating characters to at most five repetitions with a maximum length of 20 for each token.
    df['token'] = df['token'].apply(lambda t: re.sub(r'(.)\1{4,}',r'\1\1\1\1', t)[:20])

Installing dependencies

You can use the pip program to install the dependencies on your own. They are all listed in the requirements.txt file.

To use this method, you would proceed as:

pip install -r requirements.txt

Model Architecture

Char2Vec

BiLSTMtagger(
  (word_embeddings): Char2Vec(
    (embeds): Embedding(300, 9, padding_idx=0)
    (conv1): Sequential(
      (0): Conv1d(9, 21, kernel_size=(3,), stride=(1,))
      (1): ReLU()
      (2): Dropout(p=0.1, inplace=False)
    )
    (convs2): ModuleList(
      (0): Sequential(
        (0): Conv1d(21, 5, kernel_size=(3,), stride=(1,))
        (1): ReLU()
      )
      (1): Sequential(
        (0): Conv1d(21, 5, kernel_size=(4,), stride=(1,))
        (1): ReLU()
      )
      (2): Sequential(
        (0): Conv1d(21, 5, kernel_size=(5,), stride=(1,))
        (1): ReLU()
      )
    )
    (linear): Sequential(
      (0): Linear(in_features=15, out_features=15, bias=True)
      (1): ReLU()
    )
  )
  (lstm): LSTM(15, 128, num_layers=2, batch_first=True, dropout=0.3, bidirectional=True)
  (hidden2tag): Linear(in_features=256, out_features=4, bias=True)
)

Model Summary

=================================================================
Layer (type:depth-idx)                   Param #
=================================================================
├─Char2Vec: 1-1                          --
|    └─Embedding: 2-1                    2,700
|    └─Sequential: 2-2                   --
|    |    └─Conv1d: 3-1                  588
|    |    └─ReLU: 3-2                    --
|    |    └─Dropout: 3-3                 --
|    └─ModuleList: 2-3                   --
|    |    └─Sequential: 3-4              320
|    |    └─Sequential: 3-5              425
|    |    └─Sequential: 3-6              530
|    └─Sequential: 2-4                   --
|    |    └─Linear: 3-7                  240
|    |    └─ReLU: 3-8                    --
├─LSTM: 1-2                              543,744
├─Linear: 1-3                            1,028
=================================================================
Total params: 549,575
Trainable params: 549,575
Non-trainable params: 0
=================================================================

How to use the code

Training

Just run train.py from code directory. It assumes that the cwd is in the code directory.

Prediction

Launch predict.py with the following arguments:

  • model: path of the pre-trained model
  • text: input text

Example usage:

python predict.py --model pretrained_model.pth --text="@lililium This is an audio book !"

Result

Running the model on the Google Colab with Tesla T4 GPU and 100 epochs, achieved the validation f1-score of 0.92.

plot

classification Report

              precision    recall  f1-score   support

          en       0.93      0.93      0.93      3028
          es       0.94      0.96      0.95      4185
       other       0.95      0.90      0.93      2370

    accuracy                           0.94      9583
   macro avg       0.94      0.93      0.94      9583
weighted avg       0.94      0.94      0.94      9583

Confusion Matrix

confusion matrix

TODO

  • Data augmentation
  • Fine tunning the model to find the best hyper-parameters

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