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GPy/GPy/kern/product_orthogonal.py
Nicolo Fusi 9c88687634 doc style change
2013-01-31 10:57:43 +00:00

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# Copyright (c) 2012, GPy authors (see AUTHORS.txt).
# Licensed under the BSD 3-clause license (see LICENSE.txt)
from kernpart import kernpart
import numpy as np
import hashlib
from scipy import integrate
class product_orthogonal(kernpart):
"""
Computes the product of 2 kernels
:param k1, k2: the kernels to multiply
:type k1, k2: kernpart
:rtype: kernel object
"""
def __init__(self,k1,k2):
assert k1._get_param_names()[0] == 'variance' and k2._get_param_names()[0] == 'variance', "Error: The multipication of kernels is only defined when the first parameters of the kernels to multiply is the variance."
self.D = k1.D + k2.D
self.Nparam = k1.Nparam + k2.Nparam - 1
self.name = k1.name + '<times>' + k2.name
self.k1 = k1
self.k2 = k2
self._set_params(np.hstack((k1._get_params()[0]*k2._get_params()[0], k1._get_params()[1:],k2._get_params()[1:])))
def _get_params(self):
"""return the value of the parameters."""
return self.params
def _set_params(self,x):
"""set the value of the parameters."""
self.k1._set_params(np.hstack((1.,x[1:self.k1.Nparam])))
self.k2._set_params(np.hstack((1.,x[self.k1.Nparam:])))
self.params = x
def _get_param_names(self):
"""return parameter names."""
return ['variance']+[self.k1.name + '_' + self.k1._get_param_names()[i+1] for i in range(self.k1.Nparam-1)] + [self.k2.name + '_' + self.k2._get_param_names()[i+1] for i in range(self.k2.Nparam-1)]
def K(self,X,X2,target):
"""Compute the covariance matrix between X and X2."""
if X2 is None: X2 = X
target1 = np.zeros((X.shape[0],X2.shape[0]))
target2 = np.zeros((X.shape[0],X2.shape[0]))
self.k1.K(X[:,0:self.k1.D],X2[:,0:self.k1.D],target1)
self.k2.K(X[:,self.k1.D:],X2[:,self.k1.D:],target2)
target += self.params[0]*target1 * target2
def Kdiag(self,X,target):
"""Compute the diagonal of the covariance matrix associated to X."""
target1 = np.zeros((X.shape[0],))
target2 = np.zeros((X.shape[0],))
self.k1.Kdiag(X[:,0:self.k1.D],target1)
self.k2.Kdiag(X[:,self.k1.D:],target2)
target += self.params[0]*target1 * target2
def dK_dtheta(self,partial,X,X2,target):
"""derivative of the covariance matrix with respect to the parameters."""
if X2 is None: X2 = X
K1 = np.zeros((X.shape[0],X2.shape[0]))
K2 = np.zeros((X.shape[0],X2.shape[0]))
self.k1.K(X[:,0:self.k1.D],X2[:,0:self.k1.D],K1)
self.k2.K(X[:,self.k1.D:],X2[:,self.k1.D:],K2)
k1_target = np.zeros(self.k1.Nparam)
k2_target = np.zeros(self.k2.Nparam)
self.k1.dK_dtheta(partial*K2, X[:,:self.k1.D], X2[:,:self.k1.D], k1_target)
self.k2.dK_dtheta(partial*K1, X[:,self.k1.D:], X2[:,self.k1.D:], k2_target)
target[0] += np.sum(K1*K2*partial)
target[1:self.k1.Nparam] += self.params[0]* k1_target[1:]
target[self.k1.Nparam:] += self.params[0]* k2_target[1:]
def dKdiag_dtheta(self,partial,X,target):
"""derivative of the diagonal of the covariance matrix with respect to the parameters."""
target[0] += 1
def dK_dX(self,partial,X,X2,target):
"""derivative of the covariance matrix with respect to X."""
if X2 is None: X2 = X
K1 = np.zeros((X.shape[0],X2.shape[0]))
K2 = np.zeros((X.shape[0],X2.shape[0]))
self.k1.K(X[:,0:self.k1.D],X2[:,0:self.k1.D],K1)
self.k2.K(X[:,self.k1.D:],X2[:,self.k1.D:],K2)
self.k1.dK_dX(partial*K2, X[:,:self.k1.D], X2[:,:self.k1.D], target)
self.k2.dK_dX(partial*K1, X[:,self.k1.D:], X2[:,self.k1.D:], target)
def dKdiag_dX(self,X,target):
pass
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