etna.transforms.embeddings.models.TSTCCEmbeddingModel#
- class TSTCCEmbeddingModel(input_dims: int, output_dims: int = 32, tc_hidden_dim: int = 32, kernel_size: int = 7, dropout: float = 0.35, timesteps: int = 7, heads: int = 1, depth: int = 4, jitter_scale_ratio: float = 1.1, max_seg: int = 4, jitter_ratio: float = 0.8, use_cosine_similarity: bool = True, n_seq_steps: int = 0, device: Literal['cpu', 'cuda'] = 'cpu', batch_size: int = 16, num_workers: int = 0)[source]#
Bases:
BaseEmbeddingModel
TSTCC embedding model.
If there are NaNs in series, embeddings will not contain NaNs.
Each following calling of
fit
method continues the learning of the same model.Using custom output_dims, set it to a value > 3 to have the loss calculated correctly.
For more details read the paper.
Notes
This model cannot be fitted with batch_size=1. So, it cannot be fitted on a dataset with 1 segment.
Model’s weights are transferred to cpu during loading.
Init TSTCCEmbeddingModel.
- Parameters:
input_dims (int) – The input dimension. For a univariate time series, this should be set to 1.
output_dims (int) – The representation dimension.
tc_hidden_dim (int) – The output dimension after temporal_contr_model.
kernel_size (int) – Kernel size of first convolution in encoder.
dropout (float) – Dropout rate in first convolution block in encoder.
timesteps (int) – The number of timestamps to predict in temporal contrasting model.
heads (int) – Number of heads in attention block in temporal contrasting model. Parameter output_dims must be a multiple of the number of heads.
depth (int) – Depth in attention block in temporal contrasting model.
n_seq_steps (int) – Max context size in temporal contrasting model.
jitter_scale_ratio (float) – Jitter ratio in weak augmentation.
max_seg (int) – Number of segments in strong augmentation.
jitter_ratio (float) – Jitter ratio in strong augmentation.
use_cosine_similarity (bool) – If True NTXentLoss uses cosine similarity, if False NTXentLoss uses dot product.
device (Literal['cpu', 'cuda']) – The device used for training and inference. To swap device, change this attribute.
batch_size (int) – The batch size (number of segments in a batch). To swap batch_size, change this attribute.
num_workers (int) – How many subprocesses to use for data loading. See (api reference
torch.utils.data.DataLoader
). To swap num_workers, change this attribute.
Methods
Create embeddings of the whole series.
Create embeddings of each series timestamp.
fit
(x[, n_epochs, lr, temperature, lambda1, ...])Fit TSTCC embedding model.
freeze
([is_freezed])Enable or disable skipping training in
fit
.load
(path)Load an object.
save
(path)Save the object.
set_params
(**params)Return new object instance with modified parameters.
to_dict
()Collect all information about etna object in dict.
Attributes
This class stores its
__init__
parameters as attributes.Return whether to skip training during
fit
.- fit(x: ndarray, n_epochs: int = 40, lr: float = 0.001, temperature: float = 0.2, lambda1: float = 1, lambda2: float = 0.7, verbose: bool = False) TSTCCEmbeddingModel [source]#
Fit TSTCC embedding model.
- Parameters:
x (ndarray) – data with shapes (n_segments, n_timestamps, input_dims).
n_epochs (int) – The number of epochs. When this reaches, the training stops.
lr (float) – The learning rate.
temperature (float) – Temperature in NTXentLoss.
lambda1 (float) – The relative weight of the first item in the loss (temporal contrasting loss).
lambda2 (float) – The relative weight of the second item in the loss (contextual contrasting loss).
verbose (bool) – Whether to print the training loss after each epoch.
- Return type:
- freeze(is_freezed: bool = True)[source]#
Enable or disable skipping training in
fit
.- Parameters:
is_freezed (bool) – whether to skip training during
fit
.
- classmethod load(path: Path) TSTCCEmbeddingModel [source]#
Load an object.
Model’s weights are transferred to cpu during loading.
- Parameters:
path (Path) – Path to load object from.
- Returns:
Loaded object.
- Return type:
- set_params(**params: dict) Self [source]#
Return new object instance with modified parameters.
Method also allows to change parameters of nested objects within the current object. For example, it is possible to change parameters of a
model
in aPipeline
.Nested parameters are expected to be in a
<component_1>.<...>.<parameter>
form, where components are separated by a dot.- Parameters:
**params (dict) – Estimator parameters
- Returns:
New instance with changed parameters
- Return type:
Self
Examples
>>> from etna.pipeline import Pipeline >>> from etna.models import NaiveModel >>> from etna.transforms import AddConstTransform >>> model = NaiveModel(lag=1) >>> transforms = [AddConstTransform(in_column="target", value=1)] >>> pipeline = Pipeline(model, transforms=transforms, horizon=3) >>> pipeline.set_params(**{"model.lag": 3, "transforms.0.value": 2}) Pipeline(model = NaiveModel(lag = 3, ), transforms = [AddConstTransform(in_column = 'target', value = 2, inplace = True, out_column = None, )], horizon = 3, )