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Informer: Beyond Efficient Transformer for Long Sequence Time-Series Forecasting (AAAI'21 Best Paper)

Python 3.8 PyTorch 1.2 cuDNN 7.3.1 License CC BY-NC-SA

This is the origin Pytorch implementation of Informer in the following paper: Informer: Beyond Efficient Transformer for Long Sequence Time-Series Forecasting. Special thanks to Jieqi Peng@cookieminions for building this repo.

🚩News(Dec 21, 2021): update repo to include improvements found in Tightly-Coupled Convolutional Transformer on Time Series Forecasting paper[1][2]. Additions include CSPAttention, Dilated Causal Convolution, Passthrough Mechanism and LogSparse Attention[3][4].

🚩News(Mar 25, 2021): We update all experiment results with hyperparameter settings.

🚩News(Feb 22, 2021): We provide Colab Examples for friendly usage.

🚩News(Feb 8, 2021): Our Informer paper has been awarded AAAI'21 Best Paper [Official][Beihang][Rutgers]! We will continue this line of research and update on this repo. Please star this repo and cite our paper if you find our work is helpful for you.



Figure 1. The architecture of Informer.

ProbSparse Attention

The self-attention scores form a long-tail distribution, where the "active" queries lie in the "head" scores and "lazy" queries lie in the "tail" area. We designed the ProbSparse Attention to select the "active" queries rather than the "lazy" queries. The ProbSparse Attention with Top-u queries forms a sparse Transformer by the probability distribution. Why not use Top-u keys? The self-attention layer's output is the re-represent of input. It is formulated as a weighted combination of values w.r.t. the score of dot-product pairs. The top queries with full keys encourage a complete re-represent of leading components in the input, and it is equivalent to selecting the "head" scores among all the dot-product pairs. If we choose Top-u keys, the full keys just preserve the trivial sum of values within the "long tail" scores but wreck the leading components' re-represent.



Figure 2. The illustration of ProbSparse Attention.

CSPAttention

A self-attention mechanism mirroring CSPNet belonging to CNN. It cuts down nearly 30% of memory occupation and 50% of time complexity of self-attention mechanism while achieving equivalent or superior forecasting accuracy. [1][2]

Dilated Causal Convolution

It replaces canonical convolution to connect self-attention blocks. It helps Transformer model acquire exponentially receptive field growth with a little more negligible computation cost. Therefore, the learning capability of Transformer is strengthened. [1][2]

Passthrough Mechanism

It concatenates feature maps of different scales of self-attention blocks, thus getting more fine-grained information. Alike to feature pyramids commonly used in CNN and image processing, it expands feature maps leading to better forecasting performance of Transformer model. [1][2]

Enviroment

use the conda env found in the environment.yml

conda create -f environment.yml

Data

The ETT dataset used in the paper can be download in the repo ETDataset. The required data files should be put into data/ETT/ folder. A demo slice of the ETT data is illustrated in the following figure. Note that the input of each dataset is zero-mean normalized in this implementation.



Figure 3. An example of the ETT data.

The ECL data and Weather data can be download here.

Reproducibility

To easily reproduce the results you can follow the next steps:

  1. Initialize the docker image using: make init.
  2. Download the datasets using: make dataset.
  3. Run each script in scripts/ using make run_module module="bash ETTh1.sh" for each script.
  4. Alternatively, run all the scripts at once:
for file in `ls scripts`; do make run_module module="bash scripts/$script"; done

Usage

Colab Examples: We provide google colabs to help reproducing and customing our repo, which includes experiments(train and test), prediction, visualization and custom data. Open In Colab

Commands for training and testing the model with ProbSparse self-attention on Dataset ETTh1, ETTh2 and ETTm1 respectively:

# ETTh1
python -u main_informer.py --model informer --data ETTh1 --attn prob --freq h

# ETTh2
python -u main_informer.py --model informer --data ETTh2 --attn prob --freq h

# ETTm1
python -u main_informer.py --model informer --data ETTm1 --attn prob --freq t

More parameter information please refer to main_informer.py.

We provide a more detailed and complete command description for training and testing the model:

python -u main_informer.py --model <model> --data <data>
--root_path <root_path> --data_path <data_path> --features <features>
--target <target> --freq <freq> --checkpoints <checkpoints>
--seq_len <seq_len> --label_len <label_len> --pred_len <pred_len>
--enc_in <enc_in> --dec_in <dec_in> --c_out <c_out> --d_model <d_model>
--n_heads <n_heads> --e_layers <e_layers> --d_layers <d_layers>
--s_layers <s_layers> --d_ff <d_ff> --factor <factor> --padding <padding>
--distil --dropout <dropout> --attn <attn> --embed <embed> --activation <activation>
--output_attention --do_predict --mix --cols <cols> --itr <itr>
--num_workers <num_workers> --train_epochs <train_epochs>
--batch_size <batch_size> --patience <patience> --des <des>
--learning_rate <learning_rate> --loss <loss> --lradj <lradj>
--use_amp --inverse --use_gpu <use_gpu> --gpu <gpu> --use_multi_gpu --devices <devices>

The detailed descriptions about the arguments are as following:

Parameter name Description of parameter
model The model of experiment. This can be set to informer, informerstack, informerlight(TBD)
data The dataset name
root_path The root path of the data file (defaults to ./data/ETT/)
data_path The data file name (defaults to ETTh1.csv)
features The forecasting task (defaults to M). This can be set to M,S,MS (M : multivariate predict multivariate, S : univariate predict univariate, MS : multivariate predict univariate)
target Target feature in S or MS task (defaults to OT)
freq Freq for time features encoding (defaults to h). This can be set to s,t,h,d,b,w,m (s:secondly, t:minutely, h:hourly, d:daily, b:business days, w:weekly, m:monthly).You can also use more detailed freq like 15min or 3h
checkpoints Location of model checkpoints (defaults to ./checkpoints/)
seq_len Input sequence length of Informer encoder (defaults to 96)
label_len Start token length of Informer decoder (defaults to 48)
pred_len Prediction sequence length (defaults to 24)
enc_in Encoder input size (defaults to 7)
dec_in Decoder input size (defaults to 7)
c_out Output size (defaults to 7)
d_model Dimension of model (defaults to 512)
n_heads Num of heads (defaults to 8)
e_layers Num of encoder layers (defaults to 2)
d_layers Num of decoder layers (defaults to 1)
s_layers Num of stack encoder layers (defaults to 3,2,1)
d_ff Dimension of fcn (defaults to 2048)
factor Probsparse attn factor (defaults to 5)
padding Padding type(defaults to 0).
distil Whether to use distilling in encoder, using this argument means not using distilling (defaults to True)
dropout The probability of dropout (defaults to 0.05)
attn Attention used in encoder (defaults to prob). This can be set to prob (informer), full (transformer)
embed Time features encoding (defaults to timeF). This can be set to timeF, fixed, learned
activation Activation function (defaults to gelu)
output_attention Whether to output attention in encoder, using this argument means outputing attention (defaults to False)
do_predict Whether to predict unseen future data, using this argument means making predictions (defaults to False)
mix Whether to use mix attention in generative decoder, using this argument means not using mix attention (defaults to True)
cols Certain cols from the data files as the input features
num_workers The num_works of Data loader (defaults to 0)
itr Experiments times (defaults to 2)
train_epochs Train epochs (defaults to 6)
batch_size The batch size of training input data (defaults to 32)
patience Early stopping patience (defaults to 3)
learning_rate Optimizer learning rate (defaults to 0.0001)
des Experiment description (defaults to test)
loss Loss function (defaults to mse)
lradj Ways to adjust the learning rate (defaults to type1)
use_amp Whether to use automatic mixed precision training, using this argument means using amp (defaults to False)
inverse Whether to inverse output data, using this argument means inversing output data (defaults to False)
use_gpu Whether to use gpu (defaults to True)
gpu The gpu no, used for training and inference (defaults to 0)
use_multi_gpu Whether to use multiple gpus, using this argument means using mulitple gpus (defaults to False)
devices Device ids of multile gpus (defaults to 0,1,2,3)

Results

We have updated the experiment results of all methods due to the change in data scaling. We are lucky that Informer gets performance improvement. Thank you @lk1983823 for reminding the data scaling in issue 41.

Besides, the experiment parameters of each data set are formated in the .sh files in the directory ./scripts/. You can refer to these parameters for experiments, and you can also adjust the parameters to obtain better mse and mae results or draw better prediction figures.



Figure 4. Univariate forecasting results.



Figure 5. Multivariate forecasting results.

FAQ

If you run into a problem like RuntimeError: The size of tensor a (98) must match the size of tensor b (96) at non-singleton dimension 1, you can check torch version or modify code about Conv1d of TokenEmbedding in models/embed.py as the way of circular padding mode in Conv1d changed in different torch versions.

Citation

If you find this repository useful in your research, please consider citing the following paper:

@inproceedings{haoyietal-informer-2021,
  author    = {Haoyi Zhou and
               Shanghang Zhang and
               Jieqi Peng and
               Shuai Zhang and
               Jianxin Li and
               Hui Xiong and
               Wancai Zhang},
  title     = {Informer: Beyond Efficient Transformer for Long Sequence Time-Series Forecasting},
  booktitle = {The Thirty-Fifth {AAAI} Conference on Artificial Intelligence, {AAAI} 2021, Virtual Conference},
  volume    = {35},
  number    = {12},
  pages     = {11106--11115},
  publisher = {{AAAI} Press},
  year      = {2021},
}

Contact

If you have any questions, feel free to contact Haoyi Zhou through Email ([email protected]) or Github issues. Pull requests are highly welcomed!

Acknowlegements

Thanks for the computing infrastructure provided by Beijing Advanced Innovation Center for Big Data and Brain Computing (BDBC). At the same time, thank you all for your attention to this work! Hits Stargazers repo roster for @zhouhaoyi/Informer2020

Reference

[1]https://arxiv.org/abs/2108.12784

[2] https://github.com/OrigamiSL/TCCT2021

[3] Li, S., Jin, X., Xuan, Y., Zhou, X., Chen, W., Wang, Y. X., & Yan, X. (2019). Enhancing the locality and breaking the memory bottleneck of transformer on time series forecasting. arXiv preprint arXiv:1907.00235.

[4]https://github.com/AIStream-Peelout/flow-forecast

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