Skip to content

Latest commit

 

History

History
140 lines (120 loc) · 7.47 KB

File metadata and controls

140 lines (120 loc) · 7.47 KB

Convolutional Recurrent Neural Networks for Relation Extraction

Deep Learning Approach for Relation Extraction Challenge(SemEval-2010 Task #8: Multi-Way Classification of Semantic Relations Between Pairs of Nominals) using Convolutional Recurrent Neural Networks.

Experimental results

Parameters Test Data Accuracy F1 score
CRNN-Max 73% 74.28
CRNN-Att 65.95% 70.14

Usage

Train

  • train data is located in "SemEval2010_task8_all_data/SemEval2010_task8_training/TRAIN_FILE.TXT"

  • Display help message:

     $ python train.py --help
     optional arguments:
    -h, --help            show this help message and exit
    --train_dir TRAIN_DIR
                         Path of train data
    --dev_sample_percentage DEV_SAMPLE_PERCENTAGE
                         Percentage of the training data to use for validation
    --max_sentence_length MAX_SENTENCE_LENGTH
                         Max sentence length in train(98)/test(70) data
                         (Default: 100)
    --word2vec WORD2VEC   Word2vec file with pre-trained embeddings
    --text_embedding_dim TEXT_EMBEDDING_DIM
                         Dimensionality of character embedding (Default: 300)
    --layers LAYERS       Size of rnn output, no (Default: 100
    --dropout_keep_prob DROPOUT_KEEP_PROB
                         Dropout keep probability (Default: 0.5)
    --pooling_type POOLING_TYPE
                         pooling method, max or att (Default: max)
    --l2_reg_lambda L2_REG_LAMBDA
                         L2 regularization lambda (Default: 3.0)
    --f1 F1               f1 filter size (Default : 2)
    --f2 F2               f2 filter size (Default : 5)
    --n_channels N_CHANNELS
                         the number of channels-output vector size, nc(Default
                         : 100
    --batch_size BATCH_SIZE
                         Batch Size (Default: 64)
    --num_epochs NUM_EPOCHS
                         Number of training epochs (Default: 100)
    --display_every DISPLAY_EVERY
                         Number of iterations to display training info.
    --evaluate_every EVALUATE_EVERY
                         Evaluate model on dev set after this many steps
    --checkpoint_every CHECKPOINT_EVERY
                         Save model after this many steps
    --num_checkpoints NUM_CHECKPOINTS
                         Number of checkpoints to store
    --learning_rate LEARNING_RATE
                         Which learning rate to start with. (Default: 1e-3)
  • Train Example:

     $ python train.py --train_dir "TRAIN_FILE.TXT" 

Evalutation

  • test data is located in "SemEval2010_task8_all_data/SemEval2010_task8_testing_keys/TEST_FILE_FULL.TXT".

  • You must give "checkpoint_dir" argument, path of checkpoint(trained neural model) file, like below example.

  • Evaluation Example:

     $ python eval.py --checkpoint_dir "runs/1523902663/checkpoints"
  • Official Evaluation of SemEval 2010 Task #8

    1. After evaluation like the example, you can get the "prediction.txt" and "answer.txt" in "result" directory.
    2. Install perl.
    3. Move to SemEval2010_task8_all_data/SemEval2010_task8_scorer-v1.2.
      $ cd SemEval2010_task8_all_data/SemEval2010_task8_scorer-v1.2
    4. Check your prediction file format.
      $ perl semeval2010_task8_format_checker.pl ../../result/prediction.txt
    5. Scoring your prediction.
      $ perl semeval2010_task8_scorer-v1.2.pl ../../result/prediction.txt ../../result/answer.txt
    6. The scorer shows the 3 evaluation reuslts for prediction. The official evaluation result, (9+1)-WAY EVALUATION TAKING DIRECTIONALITY INTO ACCOUNT -- OFFICIAL, is the last one. See the README for more details.

SemEval-2010 Task #8

  • Given: a pair of nominals
  • Goal: recognize the semantic relation between these nominals.
  • Example:
    • "There were apples, pears and oranges in the bowl."
      CONTENT-CONTAINER(pears, bowl)
    • “The cup contained tea from dried ginseng.”
      ENTITY-ORIGIN(tea, ginseng)

The Inventory of Semantic Relations

  1. Cause-Effect(CE): An event or object leads to an effect(those cancers were caused by radiation exposures)
  2. Instrument-Agency(IA): An agent uses an instrument(phone operator)
  3. Product-Producer(PP): A producer causes a product to exist (a factory manufactures suits)
  4. Content-Container(CC): An object is physically stored in a delineated area of space (a bottle full of honey was weighed) Hendrickx, Kim, Kozareva, Nakov, O S´ eaghdha, Pad ´ o,´ Pennacchiotti, Romano, Szpakowicz Task Overview Data Creation Competition Results and Discussion The Inventory of Semantic Relations (III)
  5. Entity-Origin(EO): An entity is coming or is derived from an origin, e.g., position or material (letters from foreign countries)
  6. Entity-Destination(ED): An entity is moving towards a destination (the boy went to bed)
  7. Component-Whole(CW): An object is a component of a larger whole (my apartment has a large kitchen)
  8. Member-Collection(MC): A member forms a nonfunctional part of a collection (there are many trees in the forest)
  9. Message-Topic(CT): An act of communication, written or spoken, is about a topic (the lecture was about semantics)
  10. OTHER: If none of the above nine relations appears to be suitable.

Distribution for Dataset

  • SemEval-2010 Task #8 Dataset [Download]
Relation Train Data Test Data Total Data
Cause-Effect 1,003 (12.54%) 328 (12.07%) 1331 (12.42%)
Instrument-Agency 504 (6.30%) 156 (5.74%) 660 (6.16%)
Product-Producer 717 (8.96%) 231 (8.50%) 948 (8.85%)
Content-Container 540 (6.75%) 192 (7.07%) 732 (6.83%)
Entity-Origin 716 (8.95%) 258 (9.50%) 974 (9.09%)
Entity-Destination 845 (10.56%) 292 (10.75%) 1137 (10.61%)
Component-Whole 941 (11.76%) 312 (11.48%) 1253 (11.69%)
Member-Collection 690 (8.63%) 233 (8.58%) 923 (8.61%)
Message-Topic 634 (7.92%) 261 (9.61%) 895 (8.35%)
Other 1,410 (17.63%) 454 (16.71%) 1864 (17.39%)
Total 8,000 (100.00%) 2,717 (100.00%) 10,717 (100.00%)

Reference

  • Learning local and global contexts using a convolutional recurrent network model for relation classification in biomedical text (CoNLL 2017), D Raj et al. [paper] [github]