symjax.nn.layers.Conv1D¶

class symjax.nn.layers.Conv1D(input, n_filters, filter_length, W=<function glorot_uniform>, b=<built-in function zeros>, stride=1, padding='VALID', trainable_W=True, trainable_b=True, inplace_W=False, inplace_b=False, W_preprocessor=None, b_preprocessor=None, input_dilations=None, filter_dilations=None)[source]¶

1-D (time) convolution

perform a dense matrix multiplication and bias shifting of the input

input

n_filters

filter_length

W=initializers.glorot_uniform

b=numpy.zeros

stride=1

padding=”VALID”

trainable_W=True

trainable_b=True

inplace_W=False

inplace_b=False

W_preprocessor=None

b_preprocessor=None

input_dilations=None

filter_dilations=None

__init__(input, n_filters, filter_length, W=<function glorot_uniform>, b=<built-in function zeros>, stride=1, padding='VALID', trainable_W=True, trainable_b=True, inplace_W=False, inplace_b=False, W_preprocessor=None, b_preprocessor=None, input_dilations=None, filter_dilations=None)[source]¶: Initialize self. See help(type(self)) for accurate signature.

Methods

`__init__`(input, n_filters, filter_length[, …])	Initialize self.
`Conv1D.add_update`
`Conv1D.add_variable`
`argmax`([axis, out])	Returns the indices of the maximum values along an axis.
`argmin`([axis, out])	Returns the indices of the minimum values along an axis.
`astype`(new_dtype)	Elementwise cast.
`cast`(new_dtype)	Elementwise cast.
`clone`(givens)
`conj`()	Return the complex conjugate, element-wise.
`conjugate`()	Return the complex conjugate, element-wise.
`Conv1D.create_tensor`
`Conv1D.create_variable`
`dot`(b, *[, precision])	Dot product of two arrays.
`expand_dims`(axis, Tuple[int, …]])	Expand the shape of an array.
`flatten`()	reshape the input into a vector
`forward`()
`imag`()	Return the imaginary part of the complex argument.
`Conv1D.init_input`
`matmul`(b, *[, precision])	Matrix product of two arrays.
`max`([axis, out, keepdims, initial, where])	Return the maximum of an array or maximum along an axis.
`mean`([axis, dtype, out, keepdims])	Compute the arithmetic mean along the specified axis.
`min`([axis, out, keepdims, initial, where])	Return the minimum of an array or minimum along an axis.
`prod`([axis, dtype, out, keepdims, initial, …])	Return the product of array elements over a given axis.
`real`()	Return the real part of the complex argument.
`repeat`(repeats[, axis, total_repeat_length])	Repeat elements of an array.
`reshape`(newshape[, order])	Gives a new shape to an array without changing its data.
`round`([decimals, out])	Round an array to the given number of decimals.
`squeeze`(axis, Tuple[int, …]] = None)	Remove single-dimensional entries from the shape of an array.
`std`([axis, dtype, out, ddof, keepdims])	Compute the standard deviation along the specified axis.
`sum`([axis, dtype, out, keepdims, initial, where])	Sum of array elements over a given axis.
`transpose`([axes])	Reverse or permute the axes of an array; returns the modified array.
`var`([axis, dtype, out, ddof, keepdims])	Compute the variance along the specified axis.
`variables`([trainable])

Attributes

`dtype`
`Conv1D.fn_name`
`name`
`ndim`
`scope`
`shape`
`Conv1D.updates`