Applies a 1D transposed convolution operator over an input image composed of several input planes.
nn_conv_transpose1d(
in_channels,
out_channels,
kernel_size,
stride = 1,
padding = 0,
output_padding = 0,
groups = 1,
bias = TRUE,
dilation = 1,
padding_mode = "zeros"
)(int): Number of channels in the input image
(int): Number of channels produced by the convolution
(int or tuple): Size of the convolving kernel
(int or tuple, optional): Stride of the convolution. Default: 1
(int or tuple, optional): dilation * (kernel_size - 1) - padding zero-padding
will be added to both sides of the input. Default: 0
(int or tuple, optional): Additional size added to one side of the output shape. Default: 0
(int, optional): Number of blocked connections from input channels to output channels. Default: 1
(bool, optional): If True, adds a learnable bias to the output. Default: TRUE
(int or tuple, optional): Spacing between kernel elements. Default: 1
(string, optional): 'zeros', 'reflect',
'replicate' or 'circular'. Default: 'zeros'
Input: \((N, C_{in}, L_{in})\)
Output: \((N, C_{out}, L_{out})\) where $$ L_{out} = (L_{in} - 1) \times \mbox{stride} - 2 \times \mbox{padding} + \mbox{dilation} \times (\mbox{kernel\_size} - 1) + \mbox{output\_padding} + 1 $$
weight (Tensor): the learnable weights of the module of shape \((\mbox{in\_channels}, \frac{\mbox{out\_channels}}{\mbox{groups}},\) \(\mbox{kernel\_size})\). The values of these weights are sampled from \(\mathcal{U}(-\sqrt{k}, \sqrt{k})\) where \(k = \frac{groups}{C_{\mbox{out}} * \mbox{kernel\_size}}\)
bias (Tensor): the learnable bias of the module of shape (out_channels).
If bias is TRUE, then the values of these weights are
sampled from \(\mathcal{U}(-\sqrt{k}, \sqrt{k})\) where
\(k = \frac{groups}{C_{\mbox{out}} * \mbox{kernel\_size}}\)
This module can be seen as the gradient of Conv1d with respect to its input. It is also known as a fractionally-strided convolution or a deconvolution (although it is not an actual deconvolution operation).
stride controls the stride for the cross-correlation.
padding controls the amount of implicit zero-paddings on both
sides for dilation * (kernel_size - 1) - padding number of points. See note
below for details.
output_padding controls the additional size added to one side
of the output shape. See note below for details.
dilation controls the spacing between the kernel points; also known as the
à trous algorithm. It is harder to describe, but this link
has a nice visualization of what dilation does.
groups controls the connections between inputs and outputs.
in_channels and out_channels must both be divisible by
groups. For example,
At groups=1, all inputs are convolved to all outputs.
At groups=2, the operation becomes equivalent to having two conv layers side by side, each seeing half the input channels, and producing half the output channels, and both subsequently concatenated.
At groups= in_channels, each input channel is convolved with
its own set of filters (of size
\(\left\lfloor\frac{out\_channels}{in\_channels}\right\rfloor\)).
if (torch_is_installed()) {
m <- nn_conv_transpose1d(32, 16, 2)
input <- torch_randn(10, 32, 2)
output <- m(input)
}
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