pypots 0.7.1

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pypots 0.7.1

Welcome to PyPOTS
a Python toolbox for machine learning on Partially-Observed Time Series





















































⦿ Motivation: Due to all kinds of reasons like failure of collection sensors, communication error,
and unexpected malfunction, missing values are common to see in time series from the real-world environment.
This makes partially-observed time series (POTS) a pervasive problem in open-world modeling and prevents advanced
data analysis. Although this problem is important, the area of machine learning on POTS still lacks a dedicated toolkit.
PyPOTS is created to fill in this blank.
⦿ Mission: PyPOTS (pronounced "Pie Pots") is born to become a handy toolbox that is going to make machine learning on POTS easy rather than
tedious, to help engineers and researchers focus more on the core problems in their hands rather than on how to deal
with the missing parts in their data. PyPOTS will keep integrating classical and the latest state-of-the-art machine learning
algorithms for partially-observed multivariate time series. For sure, besides various algorithms, PyPOTS is going to
have unified APIs together with detailed documentation and interactive examples across algorithms as tutorials.
🤗 Please star this repo to help others notice PyPOTS if you think it is a useful toolkit.
Please properly cite PyPOTS in your publications
if it helps with your research. This really means a lot to our open-source research. Thank you!
The rest of this readme file is organized as follows:
❖ Available Algorithms,
❖ PyPOTS Ecosystem,
❖ Installation,
❖ Usage,
❖ Citing PyPOTS,
❖ Contribution,
❖ Community.
❖ Available Algorithms
PyPOTS supports imputation, classification, clustering, forecasting, and anomaly detection tasks on multivariate partially-observed
time series with missing values. The table below shows the availability of each algorithm (sorted by Year) in PyPOTS for different tasks.
The symbol ✅ indicates the algorithm is available for the corresponding task (note that models will be continuously updated
in the future to handle tasks that are not currently supported. Stay tuned❗️).
🌟 Since v0.2, all neural-network models in PyPOTS has got hyperparameter-optimization support.
This functionality is implemented with the Microsoft NNI framework. You may want to refer to our time-series
imputation survey repo Awesome_Imputation to see how to config and
tune the hyperparameters.
🔥 Note that all models whose name with 🧑‍🔧 in the table (e.g. Transformer, iTransformer, Informer etc.) are not originally
proposed as algorithms for POTS data in their papers, and they cannot directly accept time series with missing values as input,
let alone imputation. To make them applicable to POTS data, we specifically apply the embedding strategy and
training approach (ORT+MIT) the same as we did in the SAITS paper[^1].
The task types are abbreviated as follows:
IMPU: Imputation;
FORE: Forecasting;
CLAS: Classification;
CLUS: Clustering;
ANOD: Anomaly Detection.
The paper references and links are all listed at the bottom of this file.



Type
Algo
IMPU
FORE
CLAS
CLUS
ANOD
Year - Venue




Neural Net
ImputeFormer🧑‍🔧[^34]





2024 - KDD


Neural Net
iTransformer🧑‍🔧[^24]





2024 - ICLR


Neural Net
SAITS[^1]





2023 - ESWA


Neural Net
FreTS🧑‍🔧[^23]





2023 - NeurIPS


Neural Net
Koopa🧑‍🔧[^29]





2023 - NeurIPS


Neural Net
Crossformer🧑‍🔧[^16]





2023 - ICLR


Neural Net
TimesNet[^14]





2023 - ICLR


Neural Net
PatchTST🧑‍🔧[^18]





2023 - ICLR


Neural Net
ETSformer🧑‍🔧[^19]





2023 - ICLR


Neural Net
MICN🧑‍🔧[^27]





2023 - ICLR


Neural Net
DLinear🧑‍🔧[^17]





2023 - AAAI


Neural Net
TiDE🧑‍🔧[^28]





2023 - TMLR


Neural Net
SCINet🧑‍🔧[^30]





2022 - NeurIPS


Neural Net
Nonstationary Tr.🧑‍🔧[^25]





2022 - NeurIPS


Neural Net
FiLM🧑‍🔧[^22]





2022 - NeurIPS


Neural Net
RevIN_SCINet🧑‍🔧[^31]





2022 - ICLR


Neural Net
Pyraformer🧑‍🔧[^26]





2022 - ICLR


Neural Net
Raindrop[^5]





2022 - ICLR


Neural Net
FEDformer🧑‍🔧[^20]





2022 - ICML


Neural Net
Autoformer🧑‍🔧[^15]





2021 - NeurIPS


Neural Net
CSDI[^12]





2021 - NeurIPS


Neural Net
Informer🧑‍🔧[^21]





2021 - AAAI


Neural Net
US-GAN[^10]





2021 - AAAI


Neural Net
CRLI[^6]





2021 - AAAI


Probabilistic
BTTF[^8]





2021 - TPAMI


Neural Net
StemGNN🧑‍🔧[^33]





2020 - NeurIPS


Neural Net
Reformer🧑‍🔧[^32]





2020 - ICLR


Neural Net
GP-VAE[^11]





2020 - AISTATS


Neural Net
VaDER[^7]





2019 - GigaSci.


Neural Net
M-RNN[^9]





2019 - TBME


Neural Net
BRITS[^3]





2018 - NeurIPS


Neural Net
GRU-D[^4]





2018 - Sci. Rep.


Neural Net
TCN🧑‍🔧[^35]





2018 - arXiv


Neural Net
Transformer🧑‍🔧[^2]





2017 - NeurIPS


Naive
Lerp








Naive
LOCF/NOCB








Naive
Mean








Naive
Median









❖ PyPOTS Ecosystem
At PyPOTS, things are related to coffee, which we're familiar with. Yes, this is a coffee universe!
As you can see, there is a coffee pot in the PyPOTS logo.
And what else? Please read on ;-)



👈 Time series datasets are taken as coffee beans at PyPOTS, and POTS datasets are incomplete coffee beans with missing parts that have their own meanings.
To make various public time-series datasets readily available to users,
Time Series Data Beans (TSDB) is created to make loading time-series datasets super easy!
Visit TSDB right now to know more about this handy tool 🛠, and it now supports a total of 172 open-source datasets!



👉 To simulate the real-world data beans with missingness, the ecosystem library PyGrinder,
a toolkit helping grind your coffee beans into incomplete ones, is created. Missing patterns fall into three categories according to Robin's theory[^13]:
MCAR (missing completely at random), MAR (missing at random), and MNAR (missing not at random).
PyGrinder supports all of them and additional functionalities related to missingness.
With PyGrinder, you can introduce synthetic missing values into your datasets with a single line of code.



👈 To fairly evaluate the performance of PyPOTS algorithms, the benchmarking suite BenchPOTS is created,
which provides standard and unified data-preprocessing pipelines to prepare datasets for measuring the performance of different
POTS algorithms on various tasks.



👉 Now the beans, grinder, and pot are ready, please have a seat on the bench and let's think about how to brew us a cup of coffee.
Tutorials are necessary! Considering the future workload, PyPOTS tutorials are released in a single repo,
and you can find them in BrewPOTS.
Take a look at it now, and learn how to brew your POTS datasets!





☕️ Welcome to the universe of PyPOTS. Enjoy it and have fun!

❖ Installation
You can refer to the installation instruction in PyPOTS documentation for a guideline with more details.
PyPOTS is available on both PyPI and Anaconda.
You can install PyPOTS like below as well as TSDB and PyGrinder:
# via pip
pip install pypots # the first time installation
pip install pypots --upgrade # update pypots to the latest version
# install from the latest source code with the latest features but may be not officially released yet
pip install https://github.com/WenjieDu/PyPOTS/archive/main.zip

# via conda
conda install -c conda-forge pypots # the first time installation
conda update -c conda-forge pypots # update pypots to the latest version

❖ Usage
Besides BrewPOTS, you can also find a simple and quick-start tutorial notebook on Google Colab


. If you have further questions, please refer to PyPOTS documentation docs.pypots.com.
You can also raise an issue or ask in our community.
We present you a usage example of imputing missing values in time series with PyPOTS below, you can click it to view.

Click here to see an example applying SAITS on PhysioNet2012 for imputation:
# Data preprocessing. Tedious, but PyPOTS can help.
import numpy as np
from sklearn.preprocessing import StandardScaler
from pygrinder import mcar
from pypots.data import load_specific_dataset
data = load_specific_dataset('physionet_2012') # PyPOTS will automatically download and extract it.
X = data['X']
num_samples = len(X['RecordID'].unique())
X = X.drop(['RecordID', 'Time'], axis = 1)
X = StandardScaler().fit_transform(X.to_numpy())
X = X.reshape(num_samples, 48, -1)
X_ori = X # keep X_ori for validation
X = mcar(X, 0.1) # randomly hold out 10% observed values as ground truth
dataset = {"X": X} # X for model input
print(X.shape) # (11988, 48, 37), 11988 samples and each sample has 48 time steps, 37 features

# Model training. This is PyPOTS showtime.
from pypots.imputation import SAITS
from pypots.utils.metrics import calc_mae
saits = SAITS(n_steps=48, n_features=37, n_layers=2, d_model=256, n_heads=4, d_k=64, d_v=64, d_ffn=128, dropout=0.1, epochs=10)
# Here I use the whole dataset as the training set because ground truth is not visible to the model, you can also split it into train/val/test sets
saits.fit(dataset) # train the model on the dataset
imputation = saits.impute(dataset) # impute the originally-missing values and artificially-missing values
indicating_mask = np.isnan(X) ^ np.isnan(X_ori) # indicating mask for imputation error calculation
mae = calc_mae(imputation, np.nan_to_num(X_ori), indicating_mask) # calculate mean absolute error on the ground truth (artificially-missing values)
saits.save("save_it_here/saits_physionet2012.pypots") # save the model for future use
saits.load("save_it_here/saits_physionet2012.pypots") # reload the serialized model file for following imputation or training


❖ Citing PyPOTS

[!TIP]
[Updates in Jun 2024] 😎 The 1st comprehensive time-seres imputation benchmark paper
TSI-Bench: Benchmarking Time Series Imputation now is public available.
The code is open source in the repo Awesome_Imputation.
With nearly 35,000 experiments, we provide a comprehensive benchmarking study on 28 imputation methods, 3 missing patterns (points, sequences, blocks),
various missing rates, and 8 real-world datasets.
[Updates in Feb 2024] 🎉 Our survey paper Deep Learning for Multivariate Time Series Imputation: A Survey has been released on arXiv.
We comprehensively review the literature of the state-of-the-art deep-learning imputation methods for time series,
provide a taxonomy for them, and discuss the challenges and future directions in this field.

The paper introducing PyPOTS is available on arXiv,
A short version of it is accepted by the 9th SIGKDD international workshop on Mining and Learning from Time Series (MiLeTS'23)).
Additionally, PyPOTS has been included as a PyTorch Ecosystem project.
We are pursuing to publish it in prestigious academic venues, e.g. JMLR (track for
Machine Learning Open Source Software). If you use PyPOTS in your work,
please cite it as below and 🌟star this repository to make others notice this library. 🤗
There are scientific research projects using PyPOTS and referencing in their papers.
Here is an incomplete list of them.
@article{du2023pypots,
title={{PyPOTS: a Python toolbox for data mining on Partially-Observed Time Series}},
author={Wenjie Du},
journal={arXiv preprint arXiv:2305.18811},
year={2023},
}

or

Wenjie Du.
PyPOTS: a Python toolbox for data mining on Partially-Observed Time Series.
arXiv, abs/2305.18811, 2023.

❖ Contribution
You're very welcome to contribute to this exciting project!
By committing your code, you'll

make your well-established model out-of-the-box for PyPOTS users to run,
and help your work obtain more exposure and impact.
Take a look at our inclusion criteria.
You can utilize the template folder in each task package (e.g.
pypots/imputation/template) to quickly start;
become one of PyPOTS contributors and
be listed as a volunteer developer on the PyPOTS website;
get mentioned in our release notes;

You can also contribute to PyPOTS by simply staring🌟 this repo to help more people notice it.
Your star is your recognition to PyPOTS, and it matters!



👏 Click here to view PyPOTS stargazers and forkers.
We're so proud to have more and more awesome users, as well as more bright ✨stars:










👀 Check out a full list of our users' affiliations on PyPOTS website here!
❖ Community
We care about the feedback from our users, so we're building PyPOTS community on

Slack. General discussion, Q&A, and our development team are here;
LinkedIn. Official announcements and news are here;
WeChat (微信公众号). We also run a group chat on WeChat,
and you can get the QR code from the official account after following it;

If you have any suggestions or want to contribute ideas or share time-series related papers, join us and tell.
PyPOTS community is open, transparent, and surely friendly. Let's work together to build and improve PyPOTS!
[^1]: Du, W., Cote, D., & Liu, Y. (2023). SAITS: Self-Attention-based Imputation for Time Series. Expert systems with applications.
[^2]: Vaswani, A., Shazeer, N.M., Parmar, N., Uszkoreit, J., Jones, L., Gomez, A.N., Kaiser, L., & Polosukhin, I. (2017). Attention is All you Need. NeurIPS 2017.
[^3]: Cao, W., Wang, D., Li, J., Zhou, H., Li, L., & Li, Y. (2018). BRITS: Bidirectional Recurrent Imputation for Time Series. NeurIPS 2018.
[^4]: Che, Z., Purushotham, S., Cho, K., Sontag, D.A., & Liu, Y. (2018). Recurrent Neural Networks for Multivariate Time Series with Missing Values. Scientific Reports.
[^5]: Zhang, X., Zeman, M., Tsiligkaridis, T., & Zitnik, M. (2022). Graph-Guided Network for Irregularly Sampled Multivariate Time Series. ICLR 2022.
[^6]: Ma, Q., Chen, C., Li, S., & Cottrell, G. W. (2021). Learning Representations for Incomplete Time Series Clustering. AAAI 2021.
[^7]: Jong, J.D., Emon, M.A., Wu, P., Karki, R., Sood, M., Godard, P., Ahmad, A., Vrooman, H.A., Hofmann-Apitius, M., & Fröhlich, H. (2019). Deep learning for clustering of multivariate clinical patient trajectories with missing values. GigaScience.
[^8]: Chen, X., & Sun, L. (2021). Bayesian Temporal Factorization for Multidimensional Time Series Prediction. IEEE transactions on pattern analysis and machine intelligence.
[^9]: Yoon, J., Zame, W. R., & van der Schaar, M. (2019). Estimating Missing Data in Temporal Data Streams Using Multi-Directional Recurrent Neural Networks. IEEE Transactions on Biomedical Engineering.
[^10]: Miao, X., Wu, Y., Wang, J., Gao, Y., Mao, X., & Yin, J. (2021). Generative Semi-supervised Learning for Multivariate Time Series Imputation. AAAI 2021.
[^11]: Fortuin, V., Baranchuk, D., Raetsch, G. & Mandt, S. (2020). GP-VAE: Deep Probabilistic Time Series Imputation. AISTATS 2020.
[^12]: Tashiro, Y., Song, J., Song, Y., & Ermon, S. (2021). CSDI: Conditional Score-based Diffusion Models for Probabilistic Time Series Imputation. NeurIPS 2021.
[^13]: Rubin, D. B. (1976). Inference and missing data. Biometrika.
[^14]: Wu, H., Hu, T., Liu, Y., Zhou, H., Wang, J., & Long, M. (2023). TimesNet: Temporal 2d-variation modeling for general time series analysis. ICLR 2023
[^15]: Wu, H., Xu, J., Wang, J., & Long, M. (2021). Autoformer: Decomposition transformers with auto-correlation for long-term series forecasting. NeurIPS 2021.
[^16]: Zhang, Y., & Yan, J. (2023). Crossformer: Transformer utilizing cross-dimension dependency for multivariate time series forecasting. ICLR 2023.
[^17]: Zeng, A., Chen, M., Zhang, L., & Xu, Q. (2023). Are transformers effective for time series forecasting?. AAAI 2023
[^18]: Nie, Y., Nguyen, N. H., Sinthong, P., & Kalagnanam, J. (2023). A time series is worth 64 words: Long-term forecasting with transformers. ICLR 2023
[^19]: Woo, G., Liu, C., Sahoo, D., Kumar, A., & Hoi, S. (2023). ETSformer: Exponential Smoothing Transformers for Time-series Forecasting. ICLR 2023
[^20]: Zhou, T., Ma, Z., Wen, Q., Wang, X., Sun, L., & Jin, R. (2022). FEDformer: Frequency enhanced decomposed transformer for long-term series forecasting. ICML 2022.
[^21]: Zhou, H., Zhang, S., Peng, J., Zhang, S., Li, J., Xiong, H., & Zhang, W. (2021). Informer: Beyond efficient transformer for long sequence time-series forecasting. AAAI 2021.
[^22]: Zhou, T., Ma, Z., Wen, Q., Sun, L., Yao, T., Yin, W., & Jin, R. (2022). FiLM: Frequency improved Legendre Memory Model for Long-term Time Series Forecasting. NeurIPS 2022.
[^23]: Yi, K., Zhang, Q., Fan, W., Wang, S., Wang, P., He, H., An, N., Lian, D., Cao, L., & Niu, Z. (2023). Frequency-domain MLPs are More Effective Learners in Time Series Forecasting. NeurIPS 2023.
[^24]: Liu, Y., Hu, T., Zhang, H., Wu, H., Wang, S., Ma, L., & Long, M. (2024). iTransformer: Inverted Transformers Are Effective for Time Series Forecasting. ICLR 2024.
[^25]: Liu, Y., Wu, H., Wang, J., & Long, M. (2022). Non-stationary Transformers: Exploring the Stationarity in Time Series Forecasting. NeurIPS 2022.
[^26]: Liu, S., Yu, H., Liao, C., Li, J., Lin, W., Liu, A. X., & Dustdar, S. (2022). Pyraformer: Low-Complexity Pyramidal Attention for Long-Range Time Series Modeling and Forecasting. ICLR 2022.
[^27]: Wang, H., Peng, J., Huang, F., Wang, J., Chen, J., & Xiao, Y. (2023). MICN: Multi-scale Local and Global Context Modeling for Long-term Series Forecasting. ICLR 2023.
[^28]: Das, A., Kong, W., Leach, A., Mathur, S., Sen, R., & Yu, R. (2023). Long-term Forecasting with TiDE: Time-series Dense Encoder. TMLR 2023.
[^29]: Liu, Y., Li, C., Wang, J., & Long, M. (2023). Koopa: Learning Non-stationary Time Series Dynamics with Koopman Predictors. NeurIPS 2023.
[^30]: Liu, M., Zeng, A., Chen, M., Xu, Z., Lai, Q., Ma, L., & Xu, Q. (2022). SCINet: Time Series Modeling and Forecasting with Sample Convolution and Interaction. NeurIPS 2022.
[^31]: Kim, T., Kim, J., Tae, Y., Park, C., Choi, J. H., & Choo, J. (2022). Reversible Instance Normalization for Accurate Time-Series Forecasting against Distribution Shift. ICLR 2022.
[^32]: Kitaev, N., Kaiser, Ł., & Levskaya, A. (2020). Reformer: The Efficient Transformer. ICLR 2020.
[^33]: Cao, D., Wang, Y., Duan, J., Zhang, C., Zhu, X., Huang, C., Tong, Y., Xu, B., Bai, J., Tong, J., & Zhang, Q. (2020). Spectral Temporal Graph Neural Network for Multivariate Time-series Forecasting. NeurIPS 2020.
[^34]: Nie, T., Qin, G., Mei, Y., & Sun, J. (2024). ImputeFormer: Low Rankness-Induced Transformers for Generalizable Spatiotemporal Imputation. KDD 2024.
[^35]: Bai, S., Kolter, J. Z., & Koltun, V. (2018). An empirical evaluation of generic convolutional and recurrent networks for sequence modeling. arXiv 2018.

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