https://github.com/GPflow/GPflow
Tip revision: 453453e865cb87e50b81d1ccdf74999b05d6fa0e authored by alexggmatthews on 26 October 2016, 14:00:45 UTC
float32
float32
Tip revision: 453453e
test_method_equivalence.py
from __future__ import print_function
import GPflow
import numpy as np
import unittest
import tensorflow as tf
class TestEquivalence(unittest.TestCase):
"""
With a Gaussian likelihood, and inducing points (where appropriate)
positioned at the data, many of the GPflow methods are equivalent (perhaps
subject to some optimization).
Here, we make 5 models that should be the same, and make sure some
similarites hold. The models are:
1) GP Regression
2) Variational GP (with the likelihood set to Gaussian)
3) Sparse variational GP (likelihood is Gaussian, inducing points
at the data)
4) Sparse variational GP (as above, but with the whitening rotation
of the inducing variables)
5) Sparse variational GP Regression (as above, but there the inducing
variables are 'collapsed' out, as in Titsias 2009)
"""
def setUp(self):
tf.reset_default_graph()
rng = np.random.RandomState(0)
X = rng.rand(20, 1)*10
Y = np.sin(X) + 0.9 * np.cos(X*1.6) + rng.randn(*X.shape) * 0.8
self.Xtest = rng.rand(10, 1)*10
m1 = GPflow.gpr.GPR(X, Y, kern=GPflow.kernels.RBF(1),
mean_function=GPflow.mean_functions.Constant())
m2 = GPflow.vgp.VGP(X, Y, GPflow.kernels.RBF(1), likelihood=GPflow.likelihoods.Gaussian(),
mean_function=GPflow.mean_functions.Constant())
m3 = GPflow.svgp.SVGP(X, Y, GPflow.kernels.RBF(1),
likelihood=GPflow.likelihoods.Gaussian(),
Z=X.copy(), q_diag=False,
mean_function=GPflow.mean_functions.Constant())
m3.Z.fixed = True
m4 = GPflow.svgp.SVGP(X, Y, GPflow.kernels.RBF(1),
likelihood=GPflow.likelihoods.Gaussian(),
Z=X.copy(), q_diag=False, whiten=True,
mean_function=GPflow.mean_functions.Constant())
m4.Z.fixed = True
m5 = GPflow.sgpr.SGPR(X, Y, GPflow.kernels.RBF(1),
Z=X.copy(),
mean_function=GPflow.mean_functions.Constant())
m5.Z.fixed = True
m6 = GPflow.sgpr.GPRFITC(X, Y, GPflow.kernels.RBF(1), Z=X.copy(),
mean_function=GPflow.mean_functions.Constant())
m6.Z.fixed = True
self.models = [m1, m2, m3, m4, m5, m6]
for m in self.models:
m.optimize(disp=False, maxiter=300)
print('.') # stop travis timing out
def test_all(self):
likelihoods = np.array([-m._objective(m.get_free_state())[0].squeeze() for m in self.models])
self.assertTrue(np.allclose(likelihoods, likelihoods[0], 1e-2))
variances, lengthscales = [], []
for m in self.models:
if hasattr(m.kern, 'rbf'):
variances.append(m.kern.rbf.variance.value)
lengthscales.append(m.kern.rbf.lengthscales.value)
else:
variances.append(m.kern.variance.value)
lengthscales.append(m.kern.lengthscales.value)
variances, lengthscales = np.array(variances), np.array(lengthscales)
self.assertTrue(np.allclose(variances, variances[0], 1e-3))
self.assertTrue(np.allclose(lengthscales, lengthscales.mean(), 1e-2))
mu0, var0 = self.models[0].predict_y(self.Xtest)
for m in self.models[1:]:
mu, var = m.predict_y(self.Xtest)
self.assertTrue(np.allclose(mu, mu0, 1e-2))
self.assertTrue(np.allclose(var, var0, 1e-2))
if __name__ == '__main__':
unittest.main()