mathLab / EZyRB

EZyRB: Easy Reduced Basis method

Table of contents

• Description
• Dependencies and installation
• Documentation
• Testing
• Examples
• How to cite
  • Recent works with EZyRB
• Authors and contributors
• How to contribute
  • Submitting a patch
• SISSA mathLab packages for reduced order modeling
• License

Description

EZyRB is a Python package that performs a data-driven model order reduction for parametrized problems exploiting the recent approaches. Such techniques are able to provide a parametric model capable to provide the real-time approximation of the solution of a generic (potentially complex and non linear) problem. The reduced model is totally built upon the numerical data obtained by the original (to reduce) model, without requiring any knowledge of the equations that describe this model, resulting in a well suited framework for industrial contexts due to its natural capability to been integrated with commercial software.

The POD-based approach

Widely exploited in the reduced basis community, the Proper Orthogonal Decomposition (also called principal analysis components) results effective also in a data-driven context, reducing dimensionality of the input data. It has been indeed exploited in several methods, like POD with Interpolation (PODI), POD with Gaussian process regression (POD-GPR) or POD with neural network (POD-NN). More in general, in the data-driven context it is usually coupled with a generic regression/interpolation techniques for the approximation of the solution.

Simple interface

The software interface has been kept as simple and intuitive as possible. Few lines of code are sufficient to built and query the reduced model, assuming the input parameters and snapshots are already available. The following lines show a minimal but working example using PODI (RBF used as interpolation method):

from ezyrb import POD, RBF, Database
from ezyrb import ReducedOrderModel as ROM

## input
params, snapshots = extract_params_and_snapshots(...) # my input data
new_param = input('The new parametric point where solution will be predicted: ')

db = Database(params, snapshots)
pod = POD('svd')
rbf = RBF()
    
rom = ROM(db, pod, rbf)
rom.fit();

rom.predict(new_param)

The package provides different reduction methods and regressors. The high level structure of the library is represented here:

classDiagram

ReducedOrderModel *-- Database
ReducedOrderModel *-- Reduction
ReducedOrderModel *-- Approximation

class ReducedOrderModel{
 database
 reduction
 approximation
 +fit()
 +predict()
 +test_error()
}
class Database{  
 parameters
 snapshots
 +add()
}
class Reduction{  
 +fit()
 +transform()
 +inverse_transform()
}
class Approximation{  
 +fit()
 +predict()
}

See the Examples section below and the Tutorials to have an idea of the potential of this package.

Dependencies and installation

EZyRB requires numpy, scipy, sklearn, matplotlib, torch, pytest (for local test) and sphinx (to generate the documentation). The code has been tested with Python3.5 version, but it should be compatible with Python3. It can be installed using pip or directly from the source code.

Installing from source

The official distribution is on GitHub, and you can clone the repository using

> git clone https://github.com/mathLab/EZyRB

To install the latest version of the package just type:

> pip install git+https://github.com/mathLab/EZyRB

Otherwise to install your own local branch you can use

> pip install -e .

To uninstall the package just use pip again:

> pip uninstall ezyrb

Documentation

EZyRB uses Sphinx for code documentation. To build the html versions of the docs simply:

> cd docs
> make html

The generated html can be found in docs/build/html. Open up the index.html you find there to browse.

Testing

We are using the Github Actions for continuous intergration testing. You can check out the current status here.

To run tests locally:

> pytest

Examples

You can find useful tutorials on how to use the package in the tutorials folder. Here we show an application taken from the automotive engineering field

The first POD modes of the pressure field on the DrivAer model.

DrivAer model online evaluation: pressure (left) and wall shear stress (right) fields and errors.

How to cite

If you use this package in your publications please cite the package as follows:

Demo et al., (2018). EZyRB: Easy Reduced Basis method. Journal of Open Source Software, 3(24), 661, https://doi.org/10.21105/joss.00661

Or if you use LaTeX:

@article{demo18ezyrb,
  Author = {Demo, Nicola and Tezzele, Marco and Rozza, Gianluigi},
  Title = {{EZyRB: Easy Reduced Basis method}},
  Journal = {The Journal of Open Source Software},
  Volume = {3},
  Number = {24},
  Pages = {661},
  Year = {2018},
  Doi = {https://doi.org/10.21105/joss.00661}
}

Recent works with EZyRB

Here there is a list of the scientific works involving EZyRB you can consult and/or cite. If you want to add one, please open a PR.

• Tezzele, Demo, Rozza. A non-intrusive approach for proper orthogonal decomposition modal coefficients reconstruction through active subspaces. Comptes Rendus de l'Academie des Sciences DataBEST 2019 Special Issue, in press. [arXiv] [bibitem] .

• Tezzele, Demo, Rozza. Shape optimization through proper orthogonal decomposition with interpolation and dynamic mode decomposition enhanced by active subspaces. In Proceedings of MARINE 2019: VIII International Conference on Computational Methods in Marine Engineering, pages 122-133, 2019. [DOI] [arXiv] [bibitem].

• Demo, Tezzele, Mola, Rozza. A complete data-driven framework for the efficient solution of parametric shape design and optimisation in naval engineering problems. In Proceedings of MARINE 2019: VIII International Conference on Computational Methods in Marine Engineering, pages 111-121, 2019. [DOI] [arXiv] [bibitem].

• Garotta, Demo, Tezzele, Carraturo, Reali, Rozza. Reduced Order Isogeometric Analysis Approach for PDEs in Parametrized Domains. Submitted, 2018. [arXiv] [bibitem].

• Tezzele, Demo, Mola, Rozza. An integrated data-driven computational pipeline with model order reduction for industrial and applied mathematics. Submitted, 2018. [arXiv] [bibitem].

• Salmoiraghi, Scardigli, Telib, Rozza. Free-form deformation, mesh morphing and reduced-order methods: enablers for efficient aerodynamic shape optimisation. International Journal of Computational Fluid Dynamics, 32:4-5, 233-247, 2018. [DOI] [arXiv] [bibitem].

• Demo, Tezzele, Gustin, Lavini, Rozza. Shape optimization by means of proper orthogonal decomposition and dynamic mode decomposition. In Technology and Science for the Ships of the Future: Proceedings of NAV 2018: 19th International Conference on Ship & Maritime Research, 2018. [DOI] [arXiv] [bibitem].

Authors and contributors

EZyRB is currently developed and mantained at SISSA mathLab by

• Nicola Demo
• Marco Tezzele

under the supervision of Prof. Gianluigi Rozza. We thank Filippo Salmoiraghi for the original idea behind this package and the major contributions.

Contact us by email for further information or questions about EZyRB, or suggest pull requests. EZyRB is at an early development stage, so contributions improving either the code or the documentation are welcome!

How to contribute

We'd love to accept your patches and contributions to this project. There are just a few small guidelines you need to follow.

Submitting a patch

1. It's generally best to start by opening a new issue describing the bug or feature you're intending to fix. Even if you think it's relatively minor, it's helpful to know what people are working on. Mention in the initial issue that you are planning to work on that bug or feature so that it can be assigned to you.

2. Follow the normal process of forking the project, and setup a new branch to work in. It's important that each group of changes be done in separate branches in order to ensure that a pull request only includes the commits related to that bug or feature.

3. To ensure properly formatted code, please make sure to use 4 spaces to indent the code. The easy way is to run on your bash the provided script: ./code_formatter.sh. You should also run pylint over your code. It's not strictly necessary that your code be completely "lint-free", but this will help you find common style issues.

4. Any significant changes should almost always be accompanied by tests. The project already has good test coverage, so look at some of the existing tests if you're unsure how to go about it. We're using coveralls that is an invaluable tools for seeing which parts of your code aren't being exercised by your tests.

5. Do your best to have well-formed commit messages for each change. This provides consistency throughout the project, and ensures that commit messages are able to be formatted properly by various git tools.

6. Finally, push the commits to your fork and submit a pull request. Please, remember to rebase properly in order to maintain a clean, linear git history.

SISSA mathLab packages for reduced order modeling

Below you can find a list of useful reduced order modelling packages from SISSA mathLab group:

• PyGeM: Python library for Geometrical Morphing, that uses free form deformation to parametrize and morph complex geometries, https://github.com/mathLab/PyGeM.
• PyDMD: Python library for Dynamic Mode Decomposition, for a data-driven model simplification based on spatiotemporal coherent structures, https://github.com/mathLab/PyDMD.
• RBniCS: reduced order modelling in FEniCS, is an implementation in FEniCS of several reduced order modelling techniques for parametrized problems, https://github.com/mathLab/RBniCS.
• BladeX: Python Package for Blade Deformation, for geometrical parametrization and bottom-up construction of propeller blades, https://github.com/mathLab/BladeX.
• ITHACA-FV: In real Time Highly Advanced Computational Applications for Finite Volumes, is C++ library based on the finite volume solver OpenFOAM. It consists of the implementation of several reduced order modeling techniques for parametrized problems, https://github.com/mathLab/ITHACA-FV.
• ITHACA-DG: In real Time Highly Advanced Computational Applications for Discontinuous Galerkin Methods, is C++ library based on the Discontinuous Galerkin Methods solver HopeFOAM. It consists of the implementation of reduced order modeling techniques for parametrized problems, https://github.com/mathLab/ITHACA-DG.
• ITHACA-SEM: In real Time Highly Advanced Computational Applications for Spectral Element Methods, is C++ library based on the spectral element solver Nektar++. It consists of the implementation of several reduced order modeling techniques for parametrized problems, https://github.com/mathLab/ITHACA-SEM.

License

See the LICENSE file for license rights and limitations (MIT).