SeparableConv1D
classkeras.layers.SeparableConv1D(
filters,
kernel_size,
strides=1,
padding="valid",
data_format=None,
dilation_rate=1,
depth_multiplier=1,
activation=None,
use_bias=True,
depthwise_initializer="glorot_uniform",
pointwise_initializer="glorot_uniform",
bias_initializer="zeros",
depthwise_regularizer=None,
pointwise_regularizer=None,
bias_regularizer=None,
activity_regularizer=None,
depthwise_constraint=None,
pointwise_constraint=None,
bias_constraint=None,
**kwargs
)
1D separable convolution layer.
This layer performs a depthwise convolution that acts separately on
channels, followed by a pointwise convolution that mixes channels.
If use_bias
is True and a bias initializer is provided,
it adds a bias vector to the output. It then optionally applies an
activation function to produce the final output.
Arguments
strides > 1
is
incompatible with dilation_rate > 1
."valid"
or "same"
(case-insensitive).
"valid"
means no padding. "same"
results in padding evenly to
the left/right or up/down of the input. When padding="same"
and
strides=1
, the output has the same size as the input."channels_last"
or "channels_first"
.
The ordering of the dimensions in the inputs. "channels_last"
corresponds to inputs with shape (batch, steps, features)
while "channels_first"
corresponds to inputs with shape
(batch, features, steps)
. It defaults to the image_data_format
value found in your Keras config file at ~/.keras/keras.json
.
If you never set it, then it will be "channels_last"
.input_channel * depth_multiplier
.None
, no activation is applied.True
, bias will be added to the output."glorot_uniform"
)
will be used."glorot_uniform"
)
will be used.Optimizer
(e.g. used
for norm constraints or value constraints for layer weights). The
function must take as input the unprojected variable and must return
the projected variable (which must have the same shape).Optimizer
.Optimizer
.Input shape
data_format="channels_last"
:
A 3D tensor with shape: (batch_shape, steps, channels)
data_format="channels_first"
:
A 3D tensor with shape: (batch_shape, channels, steps)
Output shape
data_format="channels_last"
:
A 3D tensor with shape: (batch_shape, new_steps, filters)
data_format="channels_first"
:
A 3D tensor with shape: (batch_shape, filters, new_steps)
Returns
A 3D tensor representing
activation(separable_conv1d(inputs, kernel) + bias)
.
Example
>>> x = np.random.rand(4, 10, 12)
>>> y = keras.layers.SeparableConv1D(3, 4, 3, 2, activation='relu')(x)
>>> print(y.shape)
(4, 4, 4)