module neuralforecast.models.bitcn
class CustomConv1d
Forward- and backward looking Conv1D
method __init__
method forward
class TCNCell
Temporal Convolutional Network Cell, consisting of CustomConv1D modules.
method __init__
method forward
class BiTCN
BiTCN
Bidirectional Temporal Convolutional Network (BiTCN) is a forecasting architecture based on two temporal convolutional networks (TCNs). The first network (‘forward’) encodes future covariates of the time series, whereas the second network (‘backward’) encodes past observations and covariates. This is a univariate model.
Args:
h(int): forecast horizon.input_size(int): considered autorregresive inputs (lags), y=[1,2,3,4] input_size=2 -> lags=[1,2].hidden_size(int): units for the TCN’s hidden state size. Default: 16.dropout(float): dropout rate used for the dropout layers throughout the architecture. Default: 0.1.futr_exog_list(list): future exogenous columns.hist_exog_list(list): historic exogenous columns.stat_exog_list(list): static exogenous columns.exclude_insample_y(bool): the model skips the autoregressive features y[t-input_size:t] if True. Default: False.loss(nn.Module): PyTorch module, instantiated train loss class from losses collection.valid_loss(nn.Module): PyTorch module, instantiated valid loss class from losses collection.max_steps(int): maximum number of training steps. Default: 1000.learning_rate(float): Learning rate between (0, 1). Default: 1e-3.num_lr_decays(int): Number of learning rate decays, evenly distributed across max_steps. Default: -1.early_stop_patience_steps(int): Number of validation iterations before early stopping. Default: -1.val_check_steps(int): Number of training steps between every validation loss check. Default: 100.batch_size(int): number of different series in each batch. Default: 32.valid_batch_size(int): number of different series in each validation and test batch, if None uses batch_size. Default: None.windows_batch_size(int): number of windows to sample in each training batch, default uses all. Default: 1024.inference_windows_batch_size(int): number of windows to sample in each inference batch, -1 uses all. Default: 1024.start_padding_enabled(bool): if True, the model will pad the time series with zeros at the beginning, by input size. Default: False.training_data_availability_threshold(Union[float, List[float]]): minimum fraction of valid data points required for training windows. Single float applies to both insample and outsample; list of two floats specifies [insample_fraction, outsample_fraction]. Default 0.0 allows windows with only 1 valid data point (current behavior). Default: 0.0.step_size(int): step size between each window of temporal data. Default: 1.scaler_type(str): type of scaler for temporal inputs normalization see temporal scalers. Default: ‘identity’.random_seed(int): random_seed for pytorch initializer and numpy generators. Default: 1.drop_last_loader(bool): if TrueTimeSeriesDataLoaderdrops last non-full batch. Default: False.alias(str): optional, Custom name of the model. Default: None.optimizer(Subclass of ‘torch.optim.Optimizer’): optional, user specified optimizer instead of the default choice (Adam).optimizer_kwargs(dict): optional, list of parameters used by the user specifiedoptimizer.lr_scheduler(Subclass of ‘torch.optim.lr_scheduler.LRScheduler’): optional, user specified lr_scheduler instead of the default choice (StepLR).lr_scheduler_kwargs(dict): optional, list of parameters used by the user specifiedlr_scheduler.dataloader_kwargs(dict): optional, list of parameters passed into the PyTorch Lightning dataloader by theTimeSeriesDataLoader.**trainer_kwargs (int): keyword trainer arguments inherited from PyTorch Lighning’s trainer.
method __init__
property automatic_optimization
If set toFalse you are responsible for calling .backward(), .step(), .zero_grad().
property current_epoch
The current epoch in theTrainer, or 0 if not attached.
property device
property device_mesh
Strategies likeModelParallelStrategy will create a device mesh that can be accessed in the :meth:~pytorch_lightning.core.hooks.ModelHooks.configure_model hook to parallelize the LightningModule.
property dtype
property example_input_array
The example input array is a specification of what the module can consume in the :meth:forward method. The return type is interpreted as follows:
- Single tensor: It is assumed the model takes a single argument, i.e.,
model.forward(model.example_input_array) - Tuple: The input array should be interpreted as a sequence of positional arguments, i.e.,
model.forward(*model.example_input_array) - Dict: The input array represents named keyword arguments, i.e.,
model.forward(**model.example_input_array)
property fabric
property global_rank
The index of the current process across all nodes and devices.property global_step
Total training batches seen across all epochs. If no Trainer is attached, this property is 0.property hparams
The collection of hyperparameters saved with :meth:save_hyperparameters. It is mutable by the user. For the frozen set of initial hyperparameters, use :attr:hparams_initial.
Returns:
Mutable hyperparameters dictionary
property hparams_initial
The collection of hyperparameters saved with :meth:save_hyperparameters. These contents are read-only. Manual updates to the saved hyperparameters can instead be performed through :attr:hparams.
Returns:
AttributeDict: immutable initial hyperparameters
property local_rank
The index of the current process within a single node.property logger
Reference to the logger object in the Trainer.property loggers
Reference to the list of loggers in the Trainer.property on_gpu
ReturnsTrue if this model is currently located on a GPU.
Useful to set flags around the LightningModule for different CPU vs GPU behavior.
property strict_loading
Determines how Lightning loads this model using.load_state_dict(..., strict=model.strict_loading).