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ConvLSTM1DCell

Description

Define the cell convolution lstm 1D layer according to its parameters. To be used for the ConvLSTM1D layer. Type : polymorphic.

 

Input parameters

 

Β parameters :Β layer parameters.

filters :Β integer, the dimensionality of the output space.
Default value β€œ3”.
Β sizeΒ :Β integer, specify the dimensions of the convolution window.
Default value “3”.
Β strideΒ :Β integer, specify the stride of the convolution.
Default value β€œ1”.
Β paddingΒ :Β boolean, False = β€œvalid” means no padding. True = β€œsame” results in padding with zeros evenly to the left/right or up/down of the input such that output has the same height/width dimension as the input.
Default value β€œFalse”.
Β activation :Β enum, activation function to use.
Default value β€œtanh”.
output_activation : enum, activation function to use.
Default value “tanh”.
recurrent_activation : enum, activation function to use for the recurrent step.
Default value “sigmoid”.
Β use_bias? :Β boolean, whether the layer uses a bias vector.
Default value β€œTrue”.
kernel_initializer : enum, initializer for the kernel weights matrix, used for the linear transformation of the inputs.
Default value “glorot_uniform”.
recurrent_initializer : enum, initializer for the recurrent_kernel weights matrix, used for the linear transformation of the recurrent state.
Default value “orthogonal”.
Β bias_initializerΒ :Β enum, initializer for the bias vector.
Default value β€œzero”.
unit_forget_bias? : boolean, if True, add 1 to the bias of the forget gate at initialization.
Default value “True”.
dropoutΒ : float, fraction of the units to drop for the linear transformation of the inputs.
Default value “0.0”.
recurrent_dropout : float, fraction of the units to drop for the linear transformation of the recurrent state.
Default value “0.0”.
Β optimizer :

Β algorithm :Β enum, (name of optimizer) for optimizer instance.
Default value β€œadam”.
Β learning_rate :Β float, define the learning rate to use.
Default value β€œ0.001”.
Β beta_1 :Β float, define the exponential decay rate for the 1st moment estimates.
Default value β€œ0.9”.
Β beta_2 :Β float, define the exponential decay rate for the 2nd moment estimates.
Default value β€œ0.999”.

Β training?Β :Β boolean, whether the layer is in training mode (can store data for backward).
Default value β€œTrue”.
Β store?Β :Β boolean, whether the layer stores the last iteration gradient (accessible via the β€œget_gradients” function).
Default value β€œFalse”.
Β update?Β :Β boolean, whether the layer’s variables should be updated during backward. Equivalent to freeze the layer.
Default value β€œTrue”.

 

Output parameters

 

ConvLSTM1DCellΒ out : layer cell convolution lstm 1D architecture.

Example

All these exemples are snippets PNG, you can drop these Snippet onto the block diagram and get the depicted code added to your VI (Do not forget to install HAIBAL library to run it).

ConvLSTM1D cell inside ConvLSTM1D layer

1 – Generate a set of data

We generate an array of data of type single and shape [samples = 10, time = 7, channels = 6, row = 5]

2 – Define graph

First, we define the first layer of the graph which is an Input layer (explicit input layer method). This layer is setup as an input array shaped [time = 7, channels = 6, row = 5].
Next, we configure the β€œcell” parameter of the ConvLSTM1D layer with the ConvLSTM1D cell.
Finally, we add to the graph the ConvLSTM1D layer.

3 – Run graph

We call the forward method and retrieve the result with the β€œPrediction 3D” method.
This method returns two variables, the first one is the layer information (cluster composed of the layer name, the graph index and the shape of the output layer) and the second one is the prediction with a shape of [samples, filters, new_row].
The output dimension depends on the parameters β€œreturn-sequences” refer to the chapter β€œDimension” of ConvLSTM1D add to graph documentation.

 

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