PyTorch Tabular aims to make Deep Learning with Tabular data easy and accessible to real-world cases and research alike. The core principles behind the design of the library are:
- Low Resistance Usability
- Easy Customization
- Scalable and Easier to Deploy
It has been built on the shoulders of giants like PyTorch(obviously), and PyTorch Lightning.
Although the installation includes PyTorch, the best and recommended way is to first install PyTorch from here, picking up the right CUDA version for your machine.
Once, you have got Pytorch installed, just use:
pip install -U “pytorch_tabular[extra]”
to install the complete library with extra dependencies (Weights&Biases & Plotly).
And :
pip install -U “pytorch_tabular”
for the bare essentials.
The sources for pytorch_tabular can be downloaded from the Github repo
_.
You can either clone the public repository:
git clone git://github.com/manujosephv/pytorch_tabular
Once you have a copy of the source, you can install it with:
cd pytorch_tabular && pip install .[extra]
For complete Documentation with tutorials visit ReadTheDocs
- FeedForward Network with Category Embedding is a simple FF network, but with an Embedding layers for the categorical columns.
- Neural Oblivious Decision Ensembles for Deep Learning on Tabular Data is a model presented in ICLR 2020 and according to the authors have beaten well-tuned Gradient Boosting models on many datasets.
- TabNet: Attentive Interpretable Tabular Learning is another model coming out of Google Research which uses Sparse Attention in multiple steps of decision making to model the output.
- Mixture Density Networks is a regression model which uses gaussian components to approximate the target function and provide a probabilistic prediction out of the box.
- AutoInt: Automatic Feature Interaction Learning via Self-Attentive Neural Networks is a model which tries to learn interactions between the features in an automated way and create a better representation and then use this representation in downstream task
- TabTransformer is an adaptation of the Transformer model for Tabular Data which creates contextual representations for categorical features.
- FT Transformer from Revisiting Deep Learning Models for Tabular Data
- Gated Additive Tree Ensemble is a novel high-performance, parameter and computationally efficient deep learning architecture for tabular data. GATE uses a gating mechanism, inspired from GRU, as a feature representation learning unit with an in-built feature selection mechanism. We combine it with an ensemble of differentiable, non-linear decision trees, re-weighted with simple self-attention to predict our desired output.
- Gated Adaptive Network for Deep Automated Learning of Features (GANDALF) is pared-down version of GATE which is more efficient and performing than GATE. GANDALF makes GFLUs the main learning unit, also introducing some speed-ups in the process. With very minimal hyperparameters to tune, this becomes an easy to use and tune model.
- DANETs: Deep Abstract Networks for Tabular Data Classification and Regression is a novel and flexible neural component for tabular data, called Abstract Layer (AbstLay), which learns to explicitly group correlative input features and generate higher-level features for semantics abstraction. A special basic block is built using AbstLays, and we construct a family of Deep Abstract Networks (DANets) for tabular data classification and regression by stacking such blocks.
Semi-Supervised Learning
- Denoising AutoEncoder is an autoencoder which learns robust feature representation, to compensate any noise in the dataset.
To implement new models, see the How to implement new models tutorial. It covers basic as well as advanced architectures.
from pytorch_tabular import TabularModel
from pytorch_tabular.models import CategoryEmbeddingModelConfig
from pytorch_tabular.config import (
DataConfig,
OptimizerConfig,
TrainerConfig,
ExperimentConfig,
)
data_config = DataConfig(
target=[
"target"
], # target should always be a list.
continuous_cols=num_col_names,
categorical_cols=cat_col_names,
)
trainer_config = TrainerConfig(
auto_lr_find=True, # Runs the LRFinder to automatically derive a learning rate
batch_size=1024,
max_epochs=100,
)
optimizer_config = OptimizerConfig()
model_config = CategoryEmbeddingModelConfig(
task="classification",
layers="1024-512-512", # Number of nodes in each layer
activation="LeakyReLU", # Activation between each layers
learning_rate=1e-3,
)
tabular_model = TabularModel(
data_config=data_config,
model_config=model_config,
optimizer_config=optimizer_config,
trainer_config=trainer_config,
)
tabular_model.fit(train=train, validation=val)
result = tabular_model.evaluate(test)
pred_df = tabular_model.predict(test)
tabular_model.save_model("examples/basic")
loaded_model = TabularModel.load_model("examples/basic")
- PyTorch Tabular – A Framework for Deep Learning for Tabular Data
- Neural Oblivious Decision Ensembles(NODE) – A State-of-the-Art Deep Learning Algorithm for Tabular Data
- Mixture Density Networks: Probabilistic Regression for Uncertainty Estimation
- Integrate Optuna Hyperparameter Tuning
- Migrate Datamodule to Polars or NVTabular for faster data loading and to handle larger than RAM datasets.
- Add GaussRank as Feature Transformation
- Have a scikit-learn compatible API
- Enable support for multi-label classification
- Keep adding more architectures
If you use PyTorch Tabular for a scientific publication, we would appreciate citations to the published software and the following paper:
@misc{joseph2021pytorch,
title={PyTorch Tabular: A Framework for Deep Learning with Tabular Data},
author={Manu Joseph},
year={2021},
eprint={2104.13638},
archivePrefix={arXiv},
primaryClass={cs.LG}
}
- Zenodo Software Citation
@software{manu_joseph_2023_7554473,
author = {Manu Joseph and
Jinu Sunil and
Jiri Borovec and
Chris Fonnesbeck and
jxtrbtk and
Andreas and
JulianRein and
Kushashwa Ravi Shrimali and
Luca Actis Grosso and
Sterling G. Baird and
Yinyu Nie},
title = {manujosephv/pytorch\_tabular: v1.0.1},
month = jan,
year = 2023,
publisher = {Zenodo},
version = {v1.0.1},
doi = {10.5281/zenodo.7554473},
url = {https://doi.org/10.5281/zenodo.7554473}
}