Metadata-Version: 2.1
Name: dynabench
Version: 0.3.6
Summary: Benchmark dataset for learning dynamical systems from data
Home-page: https://dynabench.github.io/about.html
License: MIT
Author: Andrzej Dulny
Author-email: andzej.dulny@gmail.com
Requires-Python: >=3.9,<3.13
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Requires-Dist: h5py (>=3.11.0,<4.0.0)
Requires-Dist: joblib (>=1.4.2,<2.0.0)
Requires-Dist: matplotlib (<=3.8)
Requires-Dist: numpy (>=1.26.4,<2.0.0)
Requires-Dist: py-pde (>=0.40.0,<0.41.0)
Requires-Dist: requests (>=2.31.0,<3.0.0)
Requires-Dist: sympy (>=1.12,<2.0)
Requires-Dist: torch (>=2.3.0,<3.0.0)
Requires-Dist: torchdiffeq (>=0.2.3,<0.3.0)
Requires-Dist: tqdm (>=4.66.2,<5.0.0)
Project-URL: Documentation, https://dynabench.github.io/
Project-URL: Repository, https://github.com/badulion/dynabench/
Description-Content-Type: text/markdown

# DynaBench

<img src="https://dynabench.github.io/_images/dynabench.svg" width="400em" align="right" />

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The *DynaBench* package started as a benchmark dataset for learning dynamical systems from low-resolution data. It has since evolved into a full-fledged package for generating synthetic data, training models, and evaluating them on various tasks concerning partial differential equations. The package is designed to be easy to use and flexible, allowing for easy extension and modification of the existing models, data generation algorithms and physical equations.

Take a look at the [documentation](https://dynabench.github.io) for more details on the package and how to use it.

## ⚡️ Getting Started

To get started with the package, you can install it via pip:

```bash
pip install dynabench
```


### Downloading data
The DynaBench package contains dozens of different equations that can be used to generate synthetic data. The easiest way to get started, however, is to use one of the original benchmark equations. These can be downloaded using the following command:

```python
from dynabench.dataset import download_equation

download_equation(equation='advection', structure='cloud', resolution='low')
```

The original benchmark dataset consists of simulations of the following equations: 

| Equation             | Components | Time Order | Spatial Order |
|----------------------|------------|------------|---------------|
| Advection            | 1          | 1          | 1             |
| Burgers'             | 2          | 1          | 2             |
| Gas Dynamics         | 4          | 1          | 2             |
| Kuramoto-Sivashinsky | 1          | 1          | 4             |
| Reaction-Diffusion   | 2          | 1          | 2             |
| Wave                 | 1          | 2          | 2             |

### Loading data

To easily load the data the dynabench package provides the `DynabenchIterator` iterator:

```python

from dynabench.dataset import DynabenchIterator

advection_iterator = DynabenchIterator(equation='advection', 
                                        structure='cloud', 
                                        resolution='low',
                                        lookback=4,
                                        rollout=16)
```

This will iterate through all downloaded simulation of the advection dataset with observation points scattered (cloud) and low resolution. 
Each sample will be a tuple containing a snapshot of the simulation at the past 4 time steps, the future 16 time steps as target as well as the coordinates of the observation points:

```python	
for sample in advection_iterator:
    x, y, points = sample

    # x is the input data with shape (lookback, n_points, n_features)
    # y is the target data with shape (rollout, n_points, n_features)
    # points are the observation points with shape (n_points, dim)
    # for the advection equation n_features=1 and dim=2
```


## ⚙️ Usage
More advanced use cases include generating data for different equations, training models, and evaluating them. The package provides a simple interface for all these tasks. 

### Example: Generating data for Cahn-Hilliard equation
The *DynaBench* package provides a simple interface for generating synthetic data for various physical systems. For example data for the [Cahn-Hilliard equation](https://en.wikipedia.org/wiki/Cahn%E2%80%93Hilliard_equation) can be generated by running:

```python
from dynabench.equation import CahnHilliardEquation
from dynabench.initial import RandomUniform
from dynabench.grid import Grid
from dynabench.solver import PyPDESolver



# Create an instance of the CahnHilliardEquation class with default parameters
pde_equation = CahnHilliardEquation()

# Create an instance of grid with default parameters
grid = Grid(grid_limits=((0, 64), (0, 64)), grid_size=(64, 64))

# generate an initial condition as a sum of 5 gaussians
intitial = RandomUniform()


# Solve the Cahn-Hilliard equation with the initial condition
solver = PyPDESolver(equation=pde_equation, grid=grid, initial_generator=intitial, parameters={'method': "RK23"})
solver.solve(t_span=[0, 100], dt_eval=1)
```

### Example: Training NeuralPDE
The *DynaBench* package provides several models that can be used to forecast the physical system. For example, to train the [NeuralPDE model](https://arxiv.org/abs/2111.07671) on the advection equation, you can use the following code snippet:

```python
from dynabench.dataset import DynabenchIterator
from torch.utils.data import DataLoader
from dynabench.model import NeuralPDE

import torch.optim as optim
import torch.nn as nn

advection_train_iterator = DynabenchIterator(split="train",
                                             equation='burgers',
                                             structure='grid',
                                             resolution='low',
                                             lookback=1,
                                             rollout=4)

train_loader = DataLoader(advection_train_iterator, batch_size=32, shuffle=True)

model = NeuralPDE(input_dim=2, hidden_channels=64, hidden_layers=3,
                  solver={'method': 'euler', 'options': {'step_size': 0.1}},
                  use_adjoint=False)

optimizer = optim.Adam(model.parameters(), lr=1e-3)
criterion = nn.MSELoss()

for epoch in range(10):
    model.train()
    for i, (x, y, p) in enumerate(train_loader):
        x, y = x[:,0].float(), y.float() # only use the first channel and convert to float32
        optimizer.zero_grad()
        y_pred = model(x, range(0, 5))
        y_pred = y_pred.transpose(0, 1)
        loss = criterion(y_pred, y)
        loss.backward()
        optimizer.step()
        print(f"Epoch: {epoch}, Batch: {i}, Loss: {loss.item()}")
```

## 📈 Benchmark Results
The original six equations have been used to evaluate the performance of various models on the task of forecasting the physical system. For this 900 spatial points have been used. The results are shown below:

- 1-step MSE

| model             |   Advection |    Burgers |   Gas Dynamics |   Kuramoto-Sivashinsky |   Reaction-Diffusion |       Wave |
|:------------------|------------:|-----------:|---------------:|-----------------------:|---------------------:|-----------:|
| CNN               | 5.30848e-05 | 0.0110988  |     0.00420368 |            0.000669837 |          0.00036918  | 0.00143387 |
| FeaSt             | 0.000130351 | 0.0116155  |     0.0162     |            0.0117867   |          0.000488848 | 0.00523298 |
| GAT               | 0.00960113  | 0.0439986  |     0.037483   |            0.0667057   |          0.00915208  | 0.0151498  |
| GCN               | 0.026397    | 0.13899    |     0.0842611  |            0.436563    |          0.164678    | 0.0382004  |
| GraphPDE          | 0.000137098 | 0.0107391  |     0.0194755  |            0.00719822  |          0.000142114 | 0.00207144 |
| KernelNN          | 6.31157e-05 | 0.0106146  |     0.013354   |            0.00668698  |          0.000187019 | 0.00542925 |
| NeuralPDE         | 8.24453e-07 | 0.0112373  |     0.00373416 |            0.000536958 |          0.000303176 | 0.00169871 |
| Persistence       | 0.0812081   | 0.0367688  |     0.186985   |            0.142243    |          0.147124    | 0.113805   |
| Point Transformer | 4.41633e-05 | 0.0103098  |     0.00724899 |            0.00489711  |          0.000141248 | 0.00238447 |
| PointGNN          | 2.82496e-05 | 0.00882528 |     0.00901649 |            0.00673036  |          0.000136059 | 0.00138772 |
| ResNet            | 2.15721e-06 | 0.0148052  |     0.00321235 |            0.000490104 |          0.000156752 | 0.00145884 |

- 16-step rollout MSE:

| model             |       Advection |   Burgers |   Gas Dynamics |   Kuramoto-Sivashinsky |   Reaction-Diffusion |     Wave |
|:------------------|----------------:|----------:|---------------:|-----------------------:|---------------------:|---------:|
| CNN               |     0.00161331  |  0.554554 |       0.995382 |            1.26011     |          0.0183483   | 0.561433 |
| FeaSt             |     1.48288     |  0.561197 |       0.819594 |            3.74448     |          0.130149    | 1.61066  |
| GAT               | 41364.1         |  0.833353 |       1.21436  |            5.68925     |          3.85506     | 2.38418  |
| GCN               |     3.51453e+13 | 13.0876   |       7.20633  |            1.70612e+24 |          1.75955e+07 | 7.89253  |
| GraphPDE          |     1.07953     |  0.729879 |       0.969208 |            2.1044      |          0.0800235   | 1.02586  |
| KernelNN          |     0.897431    |  0.72716  |       0.854015 |            2.00334     |          0.0635278   | 1.57885  |
| NeuralPDE         |     0.000270308 |  0.659789 |       0.443498 |            1.05564     |          0.0224155   | 0.247704 |
| Persistence       |     2.39393     |  0.679261 |       1.457    |            1.89752     |          0.275678    | 2.61281  |
| Point Transformer |     0.617025    |  0.503865 |       0.642879 |            2.09746     |          0.0564399   | 1.27343  |
| PointGNN          |     0.660665    |  1.04342  |       0.759257 |            2.82063     |          0.0582293   | 1.30743  |
| ResNet            |     8.64621e-05 |  1.86352  |       0.480284 |            1.0697      |          0.00704612  | 0.299457 |

## 📃 Citing
If you use *DynaBench* for your research, please cite:

```bibtex
@inproceedings{dulny2023dynabench,
    author = {Dulny, Andrzej and Hotho, Andreas and Krause, Anna},
    title = {DynaBench: A Benchmark Dataset for Learning Dynamical Systems from Low-Resolution Data},
    year = {2023},
    isbn = {978-3-031-43411-2},
    publisher = {Springer-Verlag},
    address = {Berlin, Heidelberg},
    doi = {10.1007/978-3-031-43412-9_26},
    booktitle = {Machine Learning and Knowledge Discovery in Databases: Research Track: European Conference, ECML PKDD 2023, Turin, Italy, September 18–22, 2023, Proceedings, Part I},
    pages = {438–455},
    numpages = {18},
    keywords = {neuralPDE, dynamical systems, benchmark, dataset},
    location = {Turin, Italy}
}
```

## 📚 More resources
- The documentation for the package can be found [here](https://dynabench.github.io).
- The original benchmark paper can be found [here](https://arxiv.org/abs/2306.05805).


## License

The content of this project itself, including the data and pretrained models, is licensed under the [Creative Commons Attribution-ShareAlike 4.0 International Public License (CC BY-SA 4.0)](https://creativecommons.org/licenses/by-sa/4.0/). The underlying source code used to generate the data and train the models is licensed under the [MIT license](LICENSE).


## References

[1] 
