RNNCell¶
- class torch.nn.RNNCell(input_size, hidden_size, bias=True, nonlinearity='tanh', device=None, dtype=None)[source][source]¶
An Elman RNN cell with tanh or ReLU non-linearity.
If
nonlinearity
is ‘relu’, then ReLU is used in place of tanh.- Parameters
input_size (int) – The number of expected features in the input x
hidden_size (int) – The number of features in the hidden state h
bias (bool) – If
False
, then the layer does not use bias weights b_ih and b_hh. Default:True
nonlinearity (str) – The non-linearity to use. Can be either
'tanh'
or'relu'
. Default:'tanh'
- Inputs: input, hidden
input: tensor containing input features
hidden: tensor containing the initial hidden state Defaults to zero if not provided.
- Outputs: h’
h’ of shape (batch, hidden_size): tensor containing the next hidden state for each element in the batch
- Shape:
input: or tensor containing input features where = input_size.
hidden: or tensor containing the initial hidden state where = hidden_size. Defaults to zero if not provided.
output: or tensor containing the next hidden state.
- Variables
weight_ih (torch.Tensor) – the learnable input-hidden weights, of shape (hidden_size, input_size)
weight_hh (torch.Tensor) – the learnable hidden-hidden weights, of shape (hidden_size, hidden_size)
bias_ih – the learnable input-hidden bias, of shape (hidden_size)
bias_hh – the learnable hidden-hidden bias, of shape (hidden_size)
Note
All the weights and biases are initialized from where
Examples:
>>> rnn = nn.RNNCell(10, 20) >>> input = torch.randn(6, 3, 10) >>> hx = torch.randn(3, 20) >>> output = [] >>> for i in range(6): ... hx = rnn(input[i], hx) ... output.append(hx)