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TensorFlow.js Example: Sentiment Analysis

This demo shows how to perform text sentiment analysis on text using the Layers API of TensorFlow.js.

It demonstrates loading a pretrained model hosted at a URL, using tf.loadLayersModel().

Two model variants are provided (CNN and LSTM). These were trained on a set of 25,000 movie reviews from IMDB, labelled as having positive or negative sentiment. This dataset is provided by Python Keras, and the models were trained in Keras as well, based on the imdb_cnn and imdb_lstm examples.

To launch the demo, do

yarn
yarn watch

See this example live!

Training your own model in tfjs-node

To train the model using tfjs-node, do

yarn
yarn train <MODEL_TYPE>

where MODEL_TYPE is a required argument that specifies what type of model is to be trained. The available options are:

  • multihot: A model that takes a multi-hot encoding of the words in the sequence. In terms of data representation and model complexity, this is the simplest model in this example.
  • flatten: A model that flattens the embedding vectors of all words in the sequence.
  • cnn: A 1D convolutional model, with a dropout layer included.
  • simpleRNN: A model that uses a SimpleRNN layer (tf.layers.simpleRNN)
  • lstm: A model that uses a LSTM laayer (tf.layers.lstm)
  • bidirectionalLSTM: A model that uses a bidirectional LSTM layer (tf.layers.bidirectional and tf.layers.lstm)

By default, the training happens on the CPU using the Eigen kernels from tfjs-node. You can make the training happen on GPU by adding the --gpu flag to the command, e.g.,

yarn train --gpu <MODEL_TYPE>

The training process will download the training data and metadata form the web if they haven't been downloaded before. After the model training completes, the model will be saved to the dist/resources folder, alongside a metadata.json file. Then when you run yarn watch, you will see a "Load local model" button in the web page, which allows you to use the locally-trained model for inference in the browser.

Other arguments of the yarn train command include:

  • --maxLen allows you to specify the sequence length.
  • --numWords allows you to specify the vocabulary size.
  • --embeddingSize allows you to adjust the dimensionality of the embedding vectors.
  • --epochs, --batchSize, and --validationSplit are training-related settings.
  • --modelSavePath allows you to specify where to store the model and metadata after training completes.
  • --embeddingFilesPrefix Prefix for the path to which to save the embedding vectors and labels files (optinal). See the section below for details.

The detailed code for training are in the file train.js.

Visualizing the word embeddings in embedding projector

If you train a word embedding-based model (e.g., cnn or lstm), you can let the yarn train script write the embedding vectors, together with the corresponding word labels, to files after the model training completes. This is done using the ``--embeddingFilesPrefix`, e.g.,

yarn train --maxLen 500 cnn --epochs 2 --embeddingFilesPrefix /tmp/imdb_embed

The above command will generate two files:

  • /tmp/imdb_embed_vectors.tsv: A tab-separated-values file that for the numeric values of the word embeddings. Each line contains the embedding vector from a word.
  • /tmp/imdb_embed_labels.tsv: A file consisting of the word labels that correspond to the vectors in the previous file. Each line is a word.

These files can be directly uploaded to the Embedding Projector (https://projector.tensorflow.org/) for visualization using the T-SNE or PCA algorithm

See example screenshot: image