# Copyright (c) 2012, James Hensman
# Licensed under the BSD 3-clause license (see LICENSE.txt)
from .posterior import Posterior
from ...util.linalg import jitchol, tdot, dtrtrs, dpotri, pdinv
from ...util import diag
import numpy as np
from . import LatentFunctionInference
log_2_pi = np.log(2*np.pi)
[docs]class FITC(LatentFunctionInference):
"""
An object for inference when the likelihood is Gaussian, but we want to do sparse inference.
The function self.inference returns a Posterior object, which summarizes
the posterior.
"""
const_jitter = 1e-6
[docs] def inference(self, kern, X, Z, likelihood, Y, mean_function=None, Y_metadata=None):
assert mean_function is None, "inference with a mean function not implemented"
num_inducing, _ = Z.shape
num_data, output_dim = Y.shape
#make sure the noise is not hetero
sigma_n = likelihood.gaussian_variance(Y_metadata)
if sigma_n.size >1:
raise NotImplementedError("no hetero noise with this implementation of FITC")
Kmm = kern.K(Z)
Knn = kern.Kdiag(X)
Knm = kern.K(X, Z)
U = Knm
#factor Kmm
diag.add(Kmm, self.const_jitter)
Kmmi, L, Li, _ = pdinv(Kmm)
#compute beta_star, the effective noise precision
LiUT = np.dot(Li, U.T)
sigma_star = Knn + sigma_n - np.sum(np.square(LiUT),0)
beta_star = 1./sigma_star
# Compute and factor A
A = tdot(LiUT*np.sqrt(beta_star)) + np.eye(num_inducing)
LA = jitchol(A)
# back substutue to get b, P, v
URiy = np.dot(U.T*beta_star,Y)
tmp, _ = dtrtrs(L, URiy, lower=1)
b, _ = dtrtrs(LA, tmp, lower=1)
tmp, _ = dtrtrs(LA, b, lower=1, trans=1)
v, _ = dtrtrs(L, tmp, lower=1, trans=1)
tmp, _ = dtrtrs(LA, Li, lower=1, trans=0)
P = tdot(tmp.T)
#compute log marginal
log_marginal = -0.5*num_data*output_dim*np.log(2*np.pi) + \
-np.sum(np.log(np.diag(LA)))*output_dim + \
0.5*output_dim*np.sum(np.log(beta_star)) + \
-0.5*np.sum(np.square(Y.T*np.sqrt(beta_star))) + \
0.5*np.sum(np.square(b))
#compute dL_dR
Uv = np.dot(U, v)
dL_dR = 0.5*(np.sum(U*np.dot(U,P), 1) - 1./beta_star + np.sum(np.square(Y), 1) - 2.*np.sum(Uv*Y, 1) + np.sum(np.square(Uv), 1))*beta_star**2
# Compute dL_dKmm
vvT_P = tdot(v.reshape(-1,1)) + P
dL_dK = 0.5*(Kmmi - vvT_P)
KiU = np.dot(Kmmi, U.T)
dL_dK += np.dot(KiU*dL_dR, KiU.T)
# Compute dL_dU
vY = np.dot(v.reshape(-1,1),Y.T)
dL_dU = vY - np.dot(vvT_P, U.T)
dL_dU *= beta_star
dL_dU -= 2.*KiU*dL_dR
dL_dthetaL = likelihood.exact_inference_gradients(dL_dR)
grad_dict = {'dL_dKmm': dL_dK, 'dL_dKdiag':dL_dR, 'dL_dKnm':dL_dU.T, 'dL_dthetaL':dL_dthetaL}
#construct a posterior object
post = Posterior(woodbury_inv=Kmmi-P, woodbury_vector=v, K=Kmm, mean=None, cov=None, K_chol=L)
return post, log_marginal, grad_dict