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"""Tests for module Unbalanced OT with entropy regularization"""
# Author: Hicham Janati <hicham.janati@inria.fr>
#
# License: MIT License
import numpy as np
import ot
import pytest
@pytest.mark.parametrize("method", ["sinkhorn"])
def test_unbalanced_convergence(method):
# test generalized sinkhorn for unbalanced OT
n = 100
rng = np.random.RandomState(42)
x = rng.randn(n, 2)
a = ot.utils.unif(n)
# make dists unbalanced
b = ot.utils.unif(n) * 1.5
M = ot.dist(x, x)
epsilon = 1.
alpha = 1.
K = np.exp(- M / epsilon)
G, log = ot.unbalanced.sinkhorn_unbalanced(a, b, M, reg=epsilon, alpha=alpha,
stopThr=1e-10, method=method,
log=True)
# check fixed point equations
fi = alpha / (alpha + epsilon)
v_final = (b / K.T.dot(log["u"])) ** fi
u_final = (a / K.dot(log["v"])) ** fi
np.testing.assert_allclose(
u_final, log["u"], atol=1e-05)
np.testing.assert_allclose(
v_final, log["v"], atol=1e-05)
def test_unbalanced_barycenter():
# test generalized sinkhorn for unbalanced OT barycenter
n = 100
rng = np.random.RandomState(42)
x = rng.randn(n, 2)
A = rng.rand(n, 2)
# make dists unbalanced
A = A * np.array([1, 2])[None, :]
M = ot.dist(x, x)
epsilon = 1.
alpha = 1.
K = np.exp(- M / epsilon)
q, log = ot.unbalanced.barycenter_unbalanced(A, M, reg=epsilon, alpha=alpha,
stopThr=1e-10,
log=True)
# check fixed point equations
fi = alpha / (alpha + epsilon)
v_final = (q[:, None] / K.T.dot(log["u"])) ** fi
u_final = (A / K.dot(log["v"])) ** fi
np.testing.assert_allclose(
u_final, log["u"], atol=1e-05)
np.testing.assert_allclose(
v_final, log["v"], atol=1e-05)
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