diff options
author | Alexandre Gramfort <alexandre.gramfort@m4x.org> | 2020-04-23 10:58:13 +0200 |
---|---|---|
committer | Alexandre Gramfort <alexandre.gramfort@m4x.org> | 2020-04-23 10:58:13 +0200 |
commit | ee9d233302cbe007a87563ac468f53a6d0c346a4 (patch) | |
tree | acfa9b7570c69897fbc08efdd649f66ae045933c /docs/source/readme.rst | |
parent | 73db416784c400eccb5cdea0b3a00ac4bd68c595 (diff) | |
parent | 8ca4d301b8110d02acc18c51e3ecd1de0c87049b (diff) |
Merge branch 'rm_travis' of github.com:agramfort/POT into rm_travis
Diffstat (limited to 'docs/source/readme.rst')
-rw-r--r-- | docs/source/readme.rst | 196 |
1 files changed, 112 insertions, 84 deletions
diff --git a/docs/source/readme.rst b/docs/source/readme.rst index 4f6af01..b00d7b7 100644 --- a/docs/source/readme.rst +++ b/docs/source/readme.rst @@ -1,49 +1,96 @@ POT: Python Optimal Transport ============================= -|PyPI version| |Anaconda Cloud| |Build Status| |Documentation Status| -|Downloads| |Anaconda downloads| |License| +|PyPI version| |Anaconda Cloud| |Build Status| |Build Status| |Codecov +Status| |Downloads| |Anaconda downloads| |License| This open source Python library provide several solvers for optimization problems related to Optimal Transport for signal, image processing and machine learning. -It provides the following solvers: - -- OT Network Flow solver for the linear program/ Earth Movers Distance - [1]. -- Entropic regularization OT solver with Sinkhorn Knopp Algorithm [2], - stabilized version [9][10] and greedy Sinkhorn [22] with optional GPU - implementation (requires cupy). +Website and documentation: https://PythonOT.github.io/ + +Source Code (MIT): https://github.com/PythonOT/POT + +POT provides the following generic OT solvers (links to examples): + +- `OT Network Simplex + solver <auto_examples/plot_OT_1D.html>`__ + for the linear program/ Earth Movers Distance [1] . +- `Conditional + gradient <auto_examples/plot_optim_OTreg.html>`__ + [6] and `Generalized conditional + gradient <auto_examples/plot_optim_OTreg.html>`__ + for regularized OT [7]. +- Entropic regularization OT solver with `Sinkhorn Knopp + Algorithm <auto_examples/plot_OT_1D.html>`__ + [2] , stabilized version [9] [10], greedy Sinkhorn [22] and + `Screening Sinkhorn + [26] <auto_examples/plot_screenkhorn_1D.html>`__ + with optional GPU implementation (requires cupy). +- Bregman projections for `Wasserstein + barycenter <auto_examples/plot_barycenter_lp_vs_entropic.html>`__ + [3], `convolutional + barycenter <auto_examples/plot_convolutional_barycenter.html>`__ + [21] and unmixing [4]. - Sinkhorn divergence [23] and entropic regularization OT from empirical data. -- Smooth optimal transport solvers (dual and semi-dual) for KL and - squared L2 regularizations [17]. -- Non regularized Wasserstein barycenters [16] with LP solver (only - small scale). -- Bregman projections for Wasserstein barycenter [3], convolutional - barycenter [21] and unmixing [4]. -- Optimal transport for domain adaptation with group lasso - regularization [5] -- Conditional gradient [6] and Generalized conditional gradient for - regularized OT [7]. -- Linear OT [14] and Joint OT matrix and mapping estimation [8]. -- Wasserstein Discriminant Analysis [11] (requires autograd + - pymanopt). -- Gromov-Wasserstein distances and barycenters ([13] and regularized - [12]) -- Stochastic Optimization for Large-scale Optimal Transport (semi-dual - problem [18] and dual problem [19]) -- Non regularized free support Wasserstein barycenters [20]. -- Unbalanced OT with KL relaxation distance and barycenter [10, 25]. -- Screening Sinkhorn Algorithm for OT [26]. -- JCPOT algorithm for multi-source domain adaptation with target shift +- `Smooth optimal transport + solvers <auto_examples/plot_OT_1D_smooth.html>`__ + (dual and semi-dual) for KL and squared L2 regularizations [17]. +- Non regularized `Wasserstein barycenters + [16] <auto_examples/plot_barycenter_lp_vs_entropic.html>`__) + with LP solver (only small scale). +- `Gromov-Wasserstein + distances <auto_examples/plot_gromov.html>`__ + and `GW + barycenters <auto_examples/plot_gromov_barycenter.html>`__ + (exact [13] and regularized [12]) +- `Fused-Gromov-Wasserstein distances + solver <auto_examples/plot_fgw.html#sphx-glr-auto-examples-plot-fgw-py>`__ + and `FGW + barycenters <auto_examples/plot_barycenter_fgw.html>`__ + [24] +- `Stochastic + solver <auto_examples/plot_stochastic.html>`__ + for Large-scale Optimal Transport (semi-dual problem [18] and dual + problem [19]) +- Non regularized `free support Wasserstein + barycenters <auto_examples/plot_free_support_barycenter.html>`__ + [20]. +- `Unbalanced + OT <auto_examples/plot_UOT_1D.html>`__ + with KL relaxation and + `barycenter <auto_examples/plot_UOT_barycenter_1D.html>`__ + [10, 25]. +- `Partial Wasserstein and + Gromov-Wasserstein <auto_examples/plot_partial_wass_and_gromov.html>`__ + (exact [29] and entropic [3] formulations). + +POT provides the following Machine Learning related solvers: + +- `Optimal transport for domain + adaptation <auto_examples/plot_otda_classes.html>`__ + with `group lasso + regularization <auto_examples/plot_otda_classes.html>`__, + `Laplacian + regularization <auto_examples/plot_otda_laplacian.html>`__ + [5] [30] and `semi supervised + setting <auto_examples/plot_otda_semi_supervised.html>`__. +- `Linear OT + mapping <auto_examples/plot_otda_linear_mapping.html>`__ + [14] and `Joint OT mapping + estimation <auto_examples/plot_otda_mapping.html>`__ + [8]. +- `Wasserstein Discriminant + Analysis <auto_examples/plot_WDA.html>`__ + [11] (requires autograd + pymanopt). +- `JCPOT algorithm for multi-source domain adaptation with target + shift <auto_examples/plot_otda_jcpot.html>`__ [27]. -- Partial Wasserstein and Gromov-Wasserstein (exact [29] and entropic - [3] formulations). -Some demonstrations (both in Python and Jupyter Notebook format) are -available in the examples folder. +Some demonstrations are available in the +`documentation <auto_examples/index.html>`__. Using and citing the toolbox ^^^^^^^^^^^^^^^^^^^^^^^^^^^^ @@ -53,10 +100,16 @@ POT using the following bibtex reference: :: + Rémi Flamary and Nicolas Courty, POT Python Optimal Transport library, Website: https://pythonot.github.io/, 2017 + +In Bibtex format: + +:: + @misc{flamary2017pot, title={POT Python Optimal Transport library}, author={Flamary, R{'e}mi and Courty, Nicolas}, - url={https://github.com/rflamary/POT}, + url={https://pythonot.github.io/}, year={2017} } @@ -180,45 +233,7 @@ Examples and Notebooks The examples folder contain several examples and use case for the library. The full documentation is available on -`Readthedocs <http://pot.readthedocs.io/>`__. - -Here is a list of the Python notebooks available -`here <https://github.com/rflamary/POT/blob/master/notebooks/>`__ if you -want a quick look: - -- `1D optimal - transport <https://github.com/rflamary/POT/blob/master/notebooks/plot_OT_1D.ipynb>`__ -- `OT Ground - Loss <https://github.com/rflamary/POT/blob/master/notebooks/plot_OT_L1_vs_L2.ipynb>`__ -- `Multiple EMD - computation <https://github.com/rflamary/POT/blob/master/notebooks/plot_compute_emd.ipynb>`__ -- `2D optimal transport on empirical - distributions <https://github.com/rflamary/POT/blob/master/notebooks/plot_OT_2D_samples.ipynb>`__ -- `1D Wasserstein - barycenter <https://github.com/rflamary/POT/blob/master/notebooks/plot_barycenter_1D.ipynb>`__ -- `OT with user provided - regularization <https://github.com/rflamary/POT/blob/master/notebooks/plot_optim_OTreg.ipynb>`__ -- `Domain adaptation with optimal - transport <https://github.com/rflamary/POT/blob/master/notebooks/plot_otda_d2.ipynb>`__ -- `Color transfer in - images <https://github.com/rflamary/POT/blob/master/notebooks/plot_otda_color_images.ipynb>`__ -- `OT mapping estimation for domain - adaptation <https://github.com/rflamary/POT/blob/master/notebooks/plot_otda_mapping.ipynb>`__ -- `OT mapping estimation for color transfer in - images <https://github.com/rflamary/POT/blob/master/notebooks/plot_otda_mapping_colors_images.ipynb>`__ -- `Wasserstein Discriminant - Analysis <https://github.com/rflamary/POT/blob/master/notebooks/plot_WDA.ipynb>`__ -- `Gromov - Wasserstein <https://github.com/rflamary/POT/blob/master/notebooks/plot_gromov.ipynb>`__ -- `Gromov Wasserstein - Barycenter <https://github.com/rflamary/POT/blob/master/notebooks/plot_gromov_barycenter.ipynb>`__ -- `Fused Gromov - Wasserstein <https://github.com/rflamary/POT/blob/master/notebooks/plot_fgw.ipynb>`__ -- `Fused Gromov Wasserstein - Barycenter <https://github.com/rflamary/POT/blob/master/notebooks/plot_barycenter_fgw.ipynb>`__ - -You can also see the notebooks with `Jupyter -nbviewer <https://nbviewer.jupyter.org/github/rflamary/POT/tree/master/notebooks/>`__. +https://PythonOT.github.io/. Acknowledgements ---------------- @@ -230,23 +245,28 @@ This toolbox has been created and is maintained by The contributors to this library are -- `Alexandre Gramfort <http://alexandre.gramfort.net/>`__ +- `Alexandre Gramfort <http://alexandre.gramfort.net/>`__ (CI) - `Laetitia Chapel <http://people.irisa.fr/Laetitia.Chapel/>`__ + (Partial OT) - `Michael Perrot <http://perso.univ-st-etienne.fr/pem82055/>`__ (Mapping estimation) - `Léo Gautheron <https://github.com/aje>`__ (GPU implementation) - `Nathalie Gayraud <https://www.linkedin.com/in/nathalie-t-h-gayraud/?ppe=1>`__ -- `Stanislas Chambon <https://slasnista.github.io/>`__ -- `Antoine Rolet <https://arolet.github.io/>`__ + (DA classes) +- `Stanislas Chambon <https://slasnista.github.io/>`__ (DA classes) +- `Antoine Rolet <https://arolet.github.io/>`__ (EMD solver debug) - Erwan Vautier (Gromov-Wasserstein) -- `Kilian Fatras <https://kilianfatras.github.io/>`__ +- `Kilian Fatras <https://kilianfatras.github.io/>`__ (Stochastic + solvers) - `Alain Rakotomamonjy <https://sites.google.com/site/alainrakotomamonjy/home>`__ -- `Vayer Titouan <https://tvayer.github.io/>`__ +- `Vayer Titouan <https://tvayer.github.io/>`__ (Gromov-Wasserstein -, + Fused-Gromov-Wasserstein) - `Hicham Janati <https://hichamjanati.github.io/>`__ (Unbalanced OT) - `Romain Tavenard <https://rtavenar.github.io/>`__ (1d Wasserstein) - `Mokhtar Z. Alaya <http://mzalaya.github.io/>`__ (Screenkhorn) +- `Ievgen Redko <https://ievred.github.io/>`__ (Laplacian DA, JCPOT) This toolbox benefit a lot from open source research and we would like to thank the following persons for providing some code (in various @@ -422,17 +442,25 @@ Gromov-Wasserstein with Applications on Positive-Unlabeled Learning <https://arxiv.org/abs/2002.08276>`__, arXiv preprint arXiv:2002.08276. +[30] Flamary R., Courty N., Tuia D., Rakotomamonjy A. (2014). `Optimal +transport with Laplacian regularization: Applications to domain +adaptation and shape +matching <https://remi.flamary.com/biblio/flamary2014optlaplace.pdf>`__, +NIPS Workshop on Optimal Transport and Machine Learning OTML, 2014. + .. |PyPI version| image:: https://badge.fury.io/py/POT.svg :target: https://badge.fury.io/py/POT .. |Anaconda Cloud| image:: https://anaconda.org/conda-forge/pot/badges/version.svg :target: https://anaconda.org/conda-forge/pot -.. |Build Status| image:: https://travis-ci.org/rflamary/POT.svg?branch=master - :target: https://travis-ci.org/rflamary/POT -.. |Documentation Status| image:: https://readthedocs.org/projects/pot/badge/?version=latest - :target: http://pot.readthedocs.io/en/latest/?badge=latest +.. |Build Status| image:: https://travis-ci.org/PythonOT/POT.svg?branch=master + :target: https://travis-ci.org/PythonOT/POT +.. |Build Status| image:: https://github.com/PythonOT/POT/workflows/build/badge.svg + :target: https://github.com/PythonOT/POT/actions +.. |Codecov Status| image:: https://codecov.io/gh/PythonOT/POT/branch/master/graph/badge.svg + :target: https://codecov.io/gh/PythonOT/POT .. |Downloads| image:: https://pepy.tech/badge/pot :target: https://pepy.tech/project/pot .. |Anaconda downloads| image:: https://anaconda.org/conda-forge/pot/badges/downloads.svg :target: https://anaconda.org/conda-forge/pot .. |License| image:: https://anaconda.org/conda-forge/pot/badges/license.svg - :target: https://github.com/rflamary/POT/blob/master/LICENSE + :target: https://github.com/PythonOT/POT/blob/master/LICENSE |