to minterpy *sth.* (transitive verb) -- to produce a multivariate polynomial representation of *sth.* .— The minterpy developers in ["Lifting the curse of dimensionality"](https://interpol.pages.hzdr.de/minterpy/fundamentals/introduction.html)
minterpy
is an open-source Python package for a multivariate generalization
of the classical Newton and Lagrange interpolation schemes as well as related tasks.
It is based on an optimized re-implementation of
the multivariate interpolation prototype algorithm (MIP) by Hecht et al.1
and thereby provides software solutions that lift the curse of dimensionality from interpolation tasks.
While interpolation occurs as the bottleneck of most computational challenges,
minterpy
aims to free empirical sciences from their computational limitations.
minterpy
is continuously extended and improved
by adding further functionality and modules that provide novel digital solutions
to a broad field of computational challenges, including but not limited to:
- multivariate interpolation
- non-linear polynomial regression
- numerical integration
- global (black-box) optimization
- surface level-set methods
- non-periodic spectral partial differential equations (PDE) solvers on flat and complex geometries
- machine learning regularization
- data reconstruction
- computational solutions in algebraic geometry
Since this implementation is a prototype,
we currently only provide the installation by self-building from source.
We recommend to using git
to get the minterpy
source:
git clone https://gitlab.hzdr.de/interpol/minterpy.git
Within the source directory,
you may use the following package manager to install minterpy
.
A best practice is to create a virtual environment for minterpy
.
You can do this with the help of conda and the environment.yaml
by:
conda env create -f environment.yaml
A new conda environment called minterpy
is created.
Activate the new environment by:
conda activate minterpy
From within the environment, install the minterpy
using pip,
pip install [-e] .[all,dev,docs]
where the flag -e
means the package is directly linked
into the python site-packages of your Python version.
The options [all,dev,docs]
refer to the requirements defined
in the options.extras_require
section in setup.cfg
.
You must not use the command python setup.py install
to install minterpy
,
as you cannot always assume the files setup.py
will always be present
in the further development of minterpy
.
Finally, if you want to deactivate the conda environment, type:
conda deactivate
Alternative to conda, you can create a new virtual environment via venv, virtualenv, or pyenv-virtualenv. See CONTRIBUTING.md for details.
With minterpy
one can easily interpolate a given function.
For instance, take the function f(x) = x\sin(10x)
in one dimension:
import numpy as np
def test_function(x):
return x * np.sin(10*x)
In order to minterpy
the function test_function
one can use the top-level function interpolate
:
import minterpy as mp
interpolant = mp.interpolate(test_function,spatial_dimension=1, poly_degree=64)
Here, interpolant is a callable function,
which can be used as a representation of test_function
.
interpolate
takes as arguments the function to interpolate,
the number of dimensions (spatial_dimension
),
and the degree of the underlying polynomial (poly_degree
).
You may adjust this parameter in order to get higher accuracy.
For the example above, a degree of 64 produces an interpolant that reproduces
the test_function
almost up to machine precision:
import matplotlib.pylab as plt
x = np.linspace(-1,1,100)
plt.plot(x,interpolant(x),label="interpolant")
plt.plot(x,test_function(x),"k.",label="test function")
plt.legend()
plt.show()
For more comprehensive examples, see the getting started guides
section of the minterpy
docs.
After installation, we encourage you to at least run the unit tests of minterpy
,
where we use pytest
to run the tests.
If you want to run all tests, type:
pytest [-vvv]
from within the minterpy
source directory.
Contributions to the minterpy
packages are highly welcome.
We recommend you have a look at the CONTRIBUTING.md first.
For a more comprehensive contribution guide visit
the Contributors section of the documentation.
This work was partly funded by the Center for Advanced Systems Understanding (CASUS) that is financed by Germany’s Federal Ministry of Education and Research (BMBF) and by the Saxony Ministry for Science, Culture and Tourism (SMWK) with tax funds on the basis of the budget approved by the Saxony State Parliament.
The core development of the minterpy
is currently done
by a small team at the Center for Advanced Systems Understanding (CASUS),
namely
- Uwe Hernandez Acosta (HZDR/CASUS) ([email protected])
- Sachin Krishnan Thekke Veettil (HZDR/CASUS) ([email protected])
- Damar Wicaksono (HZDR/CASUS) ([email protected])
- Janina Schreiber (HZDR/CASUS) ([email protected])
- Michael Hecht (HZDR/CASUS) ([email protected])
- Klaus Steiniger (HZDR)
- Patrick Stiller (HZDR)
- Matthias Werner (HZDR)
- Krzysztof Gonciarz (MPI-CBG,CSBD)
- Attila Cangi (HZDR/CASUS)
- Michael Bussmann (HZDR/CASUS)
This package would not be possible without many contributions done from the community as well. For that, we want to send big thanks to:
- the guy who will show me how to include a list of contributors on github/gitlab
MIT © minterpy development team