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diff --git a/docs/source/auto_examples/plot_OTDA_mapping.rst b/docs/source/auto_examples/plot_OTDA_mapping.rst deleted file mode 100644 index 18da90d..0000000 --- a/docs/source/auto_examples/plot_OTDA_mapping.rst +++ /dev/null @@ -1,186 +0,0 @@ - - -.. _sphx_glr_auto_examples_plot_OTDA_mapping.py: - - -=============================================== -OT mapping estimation for domain adaptation [8] -=============================================== - -[8] M. Perrot, N. Courty, R. Flamary, A. Habrard, "Mapping estimation for - discrete optimal transport", Neural Information Processing Systems (NIPS), 2016. - - - - -.. rst-class:: sphx-glr-horizontal - - - * - - .. image:: /auto_examples/images/sphx_glr_plot_OTDA_mapping_001.png - :scale: 47 - - * - - .. image:: /auto_examples/images/sphx_glr_plot_OTDA_mapping_002.png - :scale: 47 - - -.. rst-class:: sphx-glr-script-out - - Out:: - - It. |Loss |Delta loss - -------------------------------- - 0|4.009366e+03|0.000000e+00 - 1|3.999933e+03|-2.352753e-03 - 2|3.999520e+03|-1.031984e-04 - 3|3.999362e+03|-3.936391e-05 - 4|3.999281e+03|-2.032868e-05 - 5|3.999238e+03|-1.083083e-05 - 6|3.999229e+03|-2.125291e-06 - It. |Loss |Delta loss - -------------------------------- - 0|4.026841e+02|0.000000e+00 - 1|3.990791e+02|-8.952439e-03 - 2|3.987954e+02|-7.107124e-04 - 3|3.986554e+02|-3.512453e-04 - 4|3.985721e+02|-2.087997e-04 - 5|3.985141e+02|-1.456184e-04 - 6|3.984729e+02|-1.034624e-04 - 7|3.984435e+02|-7.366943e-05 - 8|3.984199e+02|-5.922497e-05 - 9|3.984016e+02|-4.593063e-05 - 10|3.983867e+02|-3.733061e-05 - - - - -| - - -.. code-block:: python - - - import numpy as np - import matplotlib.pylab as pl - import ot - - - - #%% dataset generation - - np.random.seed(0) # makes example reproducible - - n=100 # nb samples in source and target datasets - theta=2*np.pi/20 - nz=0.1 - xs,ys=ot.datasets.get_data_classif('gaussrot',n,nz=nz) - xt,yt=ot.datasets.get_data_classif('gaussrot',n,theta=theta,nz=nz) - - # one of the target mode changes its variance (no linear mapping) - xt[yt==2]*=3 - xt=xt+4 - - - #%% plot samples - - pl.figure(1,(8,5)) - pl.clf() - - pl.scatter(xs[:,0],xs[:,1],c=ys,marker='+',label='Source samples') - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples') - - pl.legend(loc=0) - pl.title('Source and target distributions') - - - - #%% OT linear mapping estimation - - eta=1e-8 # quadratic regularization for regression - mu=1e0 # weight of the OT linear term - bias=True # estimate a bias - - ot_mapping=ot.da.OTDA_mapping_linear() - ot_mapping.fit(xs,xt,mu=mu,eta=eta,bias=bias,numItermax = 20,verbose=True) - - xst=ot_mapping.predict(xs) # use the estimated mapping - xst0=ot_mapping.interp() # use barycentric mapping - - - pl.figure(2,(10,7)) - pl.clf() - pl.subplot(2,2,1) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.3) - pl.scatter(xst0[:,0],xst0[:,1],c=ys,marker='+',label='barycentric mapping') - pl.title("barycentric mapping") - - pl.subplot(2,2,2) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.3) - pl.scatter(xst[:,0],xst[:,1],c=ys,marker='+',label='Learned mapping') - pl.title("Learned mapping") - - - - #%% Kernel mapping estimation - - eta=1e-5 # quadratic regularization for regression - mu=1e-1 # weight of the OT linear term - bias=True # estimate a bias - sigma=1 # sigma bandwidth fot gaussian kernel - - - ot_mapping_kernel=ot.da.OTDA_mapping_kernel() - ot_mapping_kernel.fit(xs,xt,mu=mu,eta=eta,sigma=sigma,bias=bias,numItermax = 10,verbose=True) - - xst_kernel=ot_mapping_kernel.predict(xs) # use the estimated mapping - xst0_kernel=ot_mapping_kernel.interp() # use barycentric mapping - - - #%% Plotting the mapped samples - - pl.figure(2,(10,7)) - pl.clf() - pl.subplot(2,2,1) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.2) - pl.scatter(xst0[:,0],xst0[:,1],c=ys,marker='+',label='Mapped source samples') - pl.title("Bary. mapping (linear)") - pl.legend(loc=0) - - pl.subplot(2,2,2) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.2) - pl.scatter(xst[:,0],xst[:,1],c=ys,marker='+',label='Learned mapping') - pl.title("Estim. mapping (linear)") - - pl.subplot(2,2,3) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.2) - pl.scatter(xst0_kernel[:,0],xst0_kernel[:,1],c=ys,marker='+',label='barycentric mapping') - pl.title("Bary. mapping (kernel)") - - pl.subplot(2,2,4) - pl.scatter(xt[:,0],xt[:,1],c=yt,marker='o',label='Target samples',alpha=.2) - pl.scatter(xst_kernel[:,0],xst_kernel[:,1],c=ys,marker='+',label='Learned mapping') - pl.title("Estim. mapping (kernel)") - -**Total running time of the script:** ( 0 minutes 0.882 seconds) - - - -.. container:: sphx-glr-footer - - - .. container:: sphx-glr-download - - :download:`Download Python source code: plot_OTDA_mapping.py <plot_OTDA_mapping.py>` - - - - .. container:: sphx-glr-download - - :download:`Download Jupyter notebook: plot_OTDA_mapping.ipynb <plot_OTDA_mapping.ipynb>` - -.. rst-class:: sphx-glr-signature - - `Generated by Sphinx-Gallery <http://sphinx-gallery.readthedocs.io>`_ |