81

Keras documentation isn't clear what this actually is. I understand we can use this to compress the input feature space into a smaller one. But how is this done from a neural design perspective? Is it an autoenocder, RBM?

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    It's a lookup table that can be trained – gokul_uf Oct 15 '16 at 15:31
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    It simply creates and indexes a weight matrix; see my detailed answer below (stackoverflow.com/a/53101566/9024698). – Poete Maudit Nov 1 '18 at 15:52
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    Although the most voted answer says it's a matrix multiplication, the source code and other answers show that in fact they're just a trainable matrix. The input words just pick the respective row in this matrix. – Daniel Möller Nov 5 '18 at 11:47
59

As far as I know, the Embedding layer is a simple matrix multiplication that transforms words into their corresponding word embeddings.

The weights of the Embedding layer are of the shape (vocabulary_size, embedding_dimension). For each training sample, its input are integers, which represent certain words. The integers are in the range of the vocabulary size. The Embedding layer transforms each integer i into the ith line of the embedding weights matrix.

In order to quickly do this as a matrix multiplication, the input integers are not stored as a list of integers but as a one-hot matrix. Therefore the input shape is (nb_words, vocabulary_size) with one non-zero value per line. If you multiply this by the embedding weights, you get the output in the shape

(nb_words, vocab_size) x (vocab_size, embedding_dim) = (nb_words, embedding_dim)

So with a simple matrix multiplication you transform all the words in a sample into the corresponding word embeddings.

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    Definitely a valid approach (see Semi-Supervised Sequence Learning ). You can also learn the embeddings with an autoencoder and then use them as initialization of the Embedding layer to reduce the complexity of you neural network (I assume that you do something else after the Embedding layer). – Lorrit Jul 7 '16 at 8:28
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    Here is a nice blogpost about word embeddings and their advantages. – sietschie Jul 27 '16 at 12:00
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    In the case that I presented, each training input is a set of words (can be a sentence). Each word is represented as one-hot vector and embedded into a dense vector. The disadvantage of this approach is that, since the input needs to be of constant length, all your sentences need to have the same number of words. An alternative would be paragraph vectors, which can embed sentences, paragraphs or even documents into vectors. – Lorrit Dec 2 '16 at 15:21
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    The Embedding layer will just optimize its weights in order to minimize the loss. Maybe that means that it will consider the semantic similarity, maybe it won't. You never know with neural networks. If you want to be sure that the embedding follows a certain formula (e.g. w2v), use the formula. If you have enough data, you might want to use the Embedding layer and train the embeddings. Just try it and check whether you like the results. – Lorrit Jul 8 '17 at 0:37
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    I agree with user36624 (answer below). Its NOT a simple matrix multiplication. – Daniel Möller May 8 '18 at 14:29
12

The Keras Embedding layer is not performing any matrix multiplication but it only:

1. creates a weight matrix of (vocabulary_size)x(embedding_dimension) dimensions

2. indexes this weight matrix


It is always useful to have a look at the source code to understand what a class does. In this case, we will have a look at the class Embedding which inherits from the base layer class called Layer.

(1) - Creating a weight matrix of (vocabulary_size)x(embedding_dimension) dimensions:

This is occuring at the build function of Embedding:

def build(self, input_shape):
    self.embeddings = self.add_weight(
        shape=(self.input_dim, self.output_dim),
        initializer=self.embeddings_initializer,
        name='embeddings',
        regularizer=self.embeddings_regularizer,
        constraint=self.embeddings_constraint,
        dtype=self.dtype)
    self.built = True

If you have a look at the base class Layer you will see that the function add_weight above simply creates a matrix of trainable weights (in this case of (vocabulary_size)x(embedding_dimension) dimensions):

def add_weight(self,
               name,
               shape,
               dtype=None,
               initializer=None,
               regularizer=None,
               trainable=True,
               constraint=None):
    """Adds a weight variable to the layer.
    # Arguments
        name: String, the name for the weight variable.
        shape: The shape tuple of the weight.
        dtype: The dtype of the weight.
        initializer: An Initializer instance (callable).
        regularizer: An optional Regularizer instance.
        trainable: A boolean, whether the weight should
            be trained via backprop or not (assuming
            that the layer itself is also trainable).
        constraint: An optional Constraint instance.
    # Returns
        The created weight variable.
    """
    initializer = initializers.get(initializer)
    if dtype is None:
        dtype = K.floatx()
    weight = K.variable(initializer(shape),
                        dtype=dtype,
                        name=name,
                        constraint=constraint)
    if regularizer is not None:
        with K.name_scope('weight_regularizer'):
            self.add_loss(regularizer(weight))
    if trainable:
        self._trainable_weights.append(weight)
    else:
        self._non_trainable_weights.append(weight)
    return weight

(2) - Indexing this weight matrix

This is occuring at the call function of Embedding:

def call(self, inputs):
    if K.dtype(inputs) != 'int32':
        inputs = K.cast(inputs, 'int32')
    out = K.gather(self.embeddings, inputs)
    return out

This functions returns the output of the Embedding layer which is K.gather(self.embeddings, inputs). What tf.keras.backend.gather exactly does is to index the weights matrix self.embeddings (see build function above) according to the inputs which should be lists of positive integers.

These lists can be retrieved for example if you pass your text/words inputs to the one_hot function of Keras which encodes a text into a list of word indexes of size n (this is NOT one hot encoding - see also this example for more info: https://machinelearningmastery.com/use-word-embedding-layers-deep-learning-keras/).


Therefore, that's all. There is no matrix multiplication.

On the contrary, the Keras Embedding layer is only useful because exactly it avoids performing a matrix multiplication and hence it economizes on some computational resources.

Otherwise, you could just use a Keras Dense layer (after you have encoded your input data) to get a matrix of trainable weights (of (vocabulary_size)x(embedding_dimension) dimensions) and then simply do the multiplication to get the output which will be exactly the same with the output of the Embedding layer.

6

To better understand any function it's a good habit to look at the source code. Here is for Embedding So basically it's a trainable look up table.

3

In Keras, the Embedding layer is NOT a simple matrix multiplication layer, but a look-up table layer (see call function below or the original definition).

def call(self, inputs):
    if K.dtype(inputs) != 'int32':
        inputs = K.cast(inputs, 'int32')
    out = K.gather(self.embeddings, inputs)
    return out

What it does is to map each a known integer n in inputs to a trainable feature vector W[n], whose dimension is the so-called embedded feature length.

  • Well when you multiply a one-hot represented set of vectors with a matrix, the product becomes a look-up. So the Embedding layer is indeed a matrix multiplication. – yannis Apr 28 '18 at 14:16
  • Except that nowhere keras performs this multiplication. It just defines "embeddings = a trainable matrix", and use the input indices to gather words from the matrix. – Daniel Möller May 8 '18 at 14:34
  • Thus, this embedding spares a lot of memory by simply not creating any one-hot version of the inputs. – Daniel Möller May 8 '18 at 14:35
0

In simple words (from the functionality point of view), it is a one-hot encoder and fully-connected layer. The layer weights are trainable.

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