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coregionalisation

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This commit is contained in:
James Hensman 2013-03-06 13:15:15 +00:00
parent f2ce47d96e
commit 613aae6417
4 changed files with 159 additions and 1 deletions
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69
GPy/examples/regression.py
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@ -75,6 +75,74 @@ def silhouette():
print(m) print(m)
return m return m
def coregionalisation_toy2():
"""
A simple demonstration of coregionalisation on two sinusoidal functions
"""
X1 = np.random.rand(50,1)*8
X2 = np.random.rand(30,1)*5
index = np.vstack((np.zeros_like(X1),np.ones_like(X2)))
X = np.hstack((np.vstack((X1,X2)),index))
Y1 = np.sin(X1) + np.random.randn(*X1.shape)*0.05
Y2 = np.sin(X2) + np.random.randn(*X2.shape)*0.05 + 2.
Y = np.vstack((Y1,Y2))
k1 = GPy.kern.rbf(1) + GPy.kern.bias(1)
k2 = GPy.kern.coregionalise(2,1)
k = k1.prod_orthogonal(k2)
m = GPy.models.GP_regression(X,Y,kernel=k)
m.constrain_fixed('rbf_var',1.)
m.constrain_positive('kappa')
m.ensure_default_constraints()
m.optimize()
pb.figure()
Xtest1 = np.hstack((np.linspace(0,9,100)[:,None],np.zeros((100,1))))
Xtest2 = np.hstack((np.linspace(0,9,100)[:,None],np.ones((100,1))))
mean, var,low,up = m.predict(Xtest1)
GPy.util.plot.gpplot(Xtest1[:,0],mean,low,up)
mean, var,low,up = m.predict(Xtest2)
GPy.util.plot.gpplot(Xtest2[:,0],mean,low,up)
pb.plot(X1[:,0],Y1[:,0],'rx',mew=2)
pb.plot(X2[:,0],Y2[:,0],'gx',mew=2)
return m
def coregionalisation_toy():
"""
A simple demonstration of coregionalisation on two sinusoidal functions
"""
X1 = np.random.rand(50,1)*8
X2 = np.random.rand(30,1)*5
index = np.vstack((np.zeros_like(X1),np.ones_like(X2)))
X = np.hstack((np.vstack((X1,X2)),index))
Y1 = np.sin(X1) + np.random.randn(*X1.shape)*0.05
Y2 = -np.sin(X2) + np.random.randn(*X2.shape)*0.05
Y = np.vstack((Y1,Y2))
k1 = GPy.kern.rbf(1)
k2 = GPy.kern.coregionalise(2,1)
k = k1.prod_orthogonal(k2)
m = GPy.models.GP_regression(X,Y,kernel=k)
m.constrain_fixed('rbf_var',1.)
m.constrain_positive('kappa')
m.ensure_default_constraints()
m.optimize()
pb.figure()
Xtest1 = np.hstack((np.linspace(0,9,100)[:,None],np.zeros((100,1))))
Xtest2 = np.hstack((np.linspace(0,9,100)[:,None],np.ones((100,1))))
mean, var,low,up = m.predict(Xtest1)
GPy.util.plot.gpplot(Xtest1[:,0],mean,low,up)
mean, var,low,up = m.predict(Xtest2)
GPy.util.plot.gpplot(Xtest2[:,0],mean,low,up)
pb.plot(X1[:,0],Y1[:,0],'rx',mew=2)
pb.plot(X2[:,0],Y2[:,0],'gx',mew=2)
return m
def multiple_optima(gene_number=937,resolution=80, model_restarts=10, seed=10000): def multiple_optima(gene_number=937,resolution=80, model_restarts=10, seed=10000):
"""Show an example of a multimodal error surface for Gaussian process regression. Gene 939 has bimodal behaviour where the noisey mode is higher.""" """Show an example of a multimodal error surface for Gaussian process regression. Gene 939 has bimodal behaviour where the noisey mode is higher."""
@ -160,3 +228,4 @@ def contour_data(data, length_scales, log_SNRs, signal_kernel_call=GPy.kern.rbf)
length_scale_lls.append(model.log_likelihood()) length_scale_lls.append(model.log_likelihood())
lls.append(length_scale_lls) lls.append(length_scale_lls)
return np.array(lls) return np.array(lls)

2
GPy/kern/__init__.py
View file

@ -2,5 +2,5 @@
# Licensed under the BSD 3-clause license (see LICENSE.txt) # Licensed under the BSD 3-clause license (see LICENSE.txt)
from constructors import rbf, Matern32, Matern52, exponential, linear, white, bias, finite_dimensional, spline, Brownian, rbf_sympy, sympykern, periodic_exponential, periodic_Matern32, periodic_Matern52, product, product_orthogonal, symmetric from constructors import rbf, Matern32, Matern52, exponential, linear, white, bias, finite_dimensional, spline, Brownian, rbf_sympy, sympykern, periodic_exponential, periodic_Matern32, periodic_Matern52, product, product_orthogonal, symmetric, coregionalise
from kern import kern from kern import kern

6
GPy/kern/constructors.py
View file

@ -21,6 +21,7 @@ from periodic_Matern52 import periodic_Matern52 as periodic_Matern52part
from product import product as productpart from product import product as productpart
from product_orthogonal import product_orthogonal as product_orthogonalpart from product_orthogonal import product_orthogonal as product_orthogonalpart
from symmetric import symmetric as symmetric_part from symmetric import symmetric as symmetric_part
from coregionalise import coregionalise as coregionalise_part
#TODO these s=constructors are not as clean as we'd like. Tidy the code up #TODO these s=constructors are not as clean as we'd like. Tidy the code up
#using meta-classes to make the objects construct properly wthout them. #using meta-classes to make the objects construct properly wthout them.
@ -274,3 +275,8 @@ def symmetric(k):
k_.parts = [symmetric_part(p) for p in k.parts] k_.parts = [symmetric_part(p) for p in k.parts]
return k_ return k_
def coregionalise(Nout,R=1, W=None, kappa=None):
p = coregionalise_part(Nout,R,W,kappa)
return kern(1,[p])

83
GPy/kern/coregionalise.py Normal file
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@ -0,0 +1,83 @@
# Copyright (c) 2012, James Hensman and Ricardo Andrade
# Licensed under the BSD 3-clause license (see LICENSE.txt)
from kernpart import kernpart
import numpy as np
from GPy.util.linalg import mdot, pdinv
class coregionalise(kernpart):
"""
Kernel for Intrisec Corregionalization Models
"""
def __init__(self,Nout,R=1, W=None, kappa=None):
self.D = 1
self.name = 'coregion'
self.Nout = Nout
self.R = R
if W is None:
self.W = np.ones((self.Nout,self.R))
else:
assert W.shape==(self.Nout,self.R)
self.W = W
if kappa is None:
kappa = np.ones(self.Nout)
else:
assert kappa.shape==(self.Nout,)
self.kappa = kappa
self.Nparam = self.Nout*(self.R + 1)
self._set_params(np.hstack([self.W.flatten(),self.kappa]))
def _get_params(self):
return np.hstack([self.W.flatten(),self.kappa])
def _set_params(self,x):
assert x.size == self.Nparam
self.kappa = x[-self.Nout:]
self.W = x[:-self.Nout].reshape(self.Nout,self.R)
self.B = np.dot(self.W,self.W.T) + np.diag(self.kappa)
def _get_param_names(self):
return sum([['W%i_%i'%(i,j) for j in range(self.R)] for i in range(self.Nout)],[]) + ['kappa_%i'%i for i in range(self.Nout)]
def K(self,index,index2,target):
index = np.asarray(index,dtype=np.int)
if index2 is None:
index2 = index
else:
index2 = np.asarray(index2,dtype=np.int)
ii,jj = np.meshgrid(index,index2)
target += self.B[ii,jj].T
def Kdiag(self,index,target):
target += np.diag(self.B)[np.asarray(index,dtype=np.int).flatten()]
def dK_dtheta(self,partial,index,index2,target):
index = np.asarray(index,dtype=np.int)
if index2 is None:
index2 = index
else:
index2 = np.asarray(index2,dtype=np.int)
ii,jj = np.meshgrid(index,index2)
PK = np.zeros((self.R,self.R))
dkappa = np.zeros(self.Nout)
partial_small = np.zeros_like(self.B)
for i in range(self.Nout):
for j in range(self.Nout):
partial_small[j,i] = np.sum(partial[(ii==i)*(jj==j)])
#print partial_small
dkappa = np.diag(partial_small)
##target += (((X2[:, None, :] * self.variances)) * partial[:,:, None]).sum(0)
dW = 2.*(self.W[:,None,:]*partial_small[:,:,None]).sum(0)
target += np.hstack([dW.flatten(),dkappa])
def dKdiag_dtheta(self,partial,index,target):
raise NotImplementedError
def dK_dX(self,partial,X,X2,target):
pass