kjordahl/bootstrap.ipynb

## bootstrap.ipynb

      
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## bootstrap.py
# -*- coding: utf-8 -*-
# <nbformat>3.0</nbformat>

# <codecell>

import numpy as np
import matplotlib.pyplot as plt
from scipy import ndimage
from sklearn.gaussian_process import GaussianProcess

# <codecell>

def pdense(x, y, sigma, M=1000):
    """ Plot probability density of y with known stddev sigma
    """
    assert len(x) == len(y) and len(x) == len(sigma)
    N = len(x)
    # TODO: better y ranging
    ymin, ymax = min(y - 2 * sigma), max(y + 2 * sigma)
    yy = np.linspace(ymin, ymax, M)
    a = [np.exp(-((Y - yy) / s) ** 2) / s for Y, s in zip(y, sigma)]
    A = np.array(a)
    A = A.reshape(N, M)
    plt.imshow(-A.T, cmap='gray', aspect='auto',
               origin='lower', extent=(min(x)[0], max(x)[0], ymin, ymax))
    plt.title('Density plot')

# <codecell>

def gpr(seed=0, N=20, M=1000, sigma=1.0):
    """ from scikits.learn demo
    """
    np.random.seed(seed)

    def f(x):
        """The function to predict."""
        return x * np.sin(x)

    X = np.linspace(0.1, 9.9, 20)
    X = np.atleast_2d(X).T
    y = f(X).ravel()
    y = np.random.normal(y, sigma)
    x = np.atleast_2d(np.linspace(0, 10, M)).T
    nugget = (sigma / y) ** 2
    gp = GaussianProcess(corr='squared_exponential', theta0=1e-1,
                         thetaL=1e-1, thetaU=1.0,
                         nugget=nugget,
                         random_start=100)
    gp.fit(X, y)
    y2, MSE = gp.predict(x, eval_MSE=True)
    s2 = np.sqrt(MSE)
    return X, y, x, y2, s2

# <codecell>

X, y, x, y2, s2 = gpr(seed=0)
plt.figure(1)
pdense(x, y2, s2, M=1000)
plt.plot(X, y, 'r.')
plt.plot(x, y2, 'b:')
a = plt.gca()
a.set_ylim(-10, 15)
plt.xlabel('$x$')
plt.ylabel('$f(x)$')
plt.show()

# <codecell>

# Run the experiment many times
N = 200
Y = np.nan * np.ones((N, len(x)))
s = np.nan * np.ones((N, len(x)))
print 'Running trial',
for i in xrange(N):
    X, y, x, y2, s2 = gpr(seed=i)
    Y[i,:] = y2
    s[i,:] = s2
    print i,
print '\nDone!'
plt.plot(x, Y.T, 'b', alpha=0.15)
a = plt.gca()
a.set_ylim(-10, 15)
plt.title('Bootstrap spaghetti plot')
plt.xlabel('$x$')
plt.ylabel('$f(x)$')
plt.show()

# <codecell>

ymin, ymax = -10, 15
bin_width = 0.15
y_bins = np.arange(ymin, ymax, bin_width)
H = np.zeros((len(y_bins)-1, len(x)))
m = np.zeros(x.shape)
for i in xrange(len(x)):
    h, e = np.histogram(Y[:,i], bins=np.arange(ymin, ymax, bin_width), density=True)
    H[:,i] = h
    m[i] = np.median(Y[:,i])
hb = ndimage.gaussian_filter(H, sigma=1)
plt.imshow(-hb, cmap='gray', aspect='auto', origin='lower',
           extent=(min(x)[0], max(x)[0], ymin, ymax))
plt.plot(x, m, 'b:')
a = plt.gca()
a.set_ylim(-10, 15)
plt.title('Bootstrap density plot')
plt.xlabel('$x$')
plt.ylabel('$f(x)$')

# <codecell>
	# -- coding: utf-8 --
	# <nbformat>3.0</nbformat>

	# <codecell>

	import numpy as np
	import matplotlib.pyplot as plt
	from scipy import ndimage
	from sklearn.gaussian_process import GaussianProcess

	# <codecell>

	def pdense(x, y, sigma, M=1000):
	""" Plot probability density of y with known stddev sigma
	"""
	assert len(x) == len(y) and len(x) == len(sigma)
	N = len(x)
	# TODO: better y ranging
	ymin, ymax = min(y - 2 * sigma), max(y + 2 * sigma)
	yy = np.linspace(ymin, ymax, M)
	a = [np.exp(-((Y - yy) / s) ** 2) / s for Y, s in zip(y, sigma)]
	A = np.array(a)
	A = A.reshape(N, M)
	plt.imshow(-A.T, cmap='gray', aspect='auto',
	origin='lower', extent=(min(x)[0], max(x)[0], ymin, ymax))
	plt.title('Density plot')

	# <codecell>

	def gpr(seed=0, N=20, M=1000, sigma=1.0):
	""" from scikits.learn demo
	"""
	np.random.seed(seed)

	def f(x):
	"""The function to predict."""
	return x * np.sin(x)

	X = np.linspace(0.1, 9.9, 20)
	X = np.atleast_2d(X).T
	y = f(X).ravel()
	y = np.random.normal(y, sigma)
	x = np.atleast_2d(np.linspace(0, 10, M)).T
	nugget = (sigma / y) ** 2
	gp = GaussianProcess(corr='squared_exponential', theta0=1e-1,
	thetaL=1e-1, thetaU=1.0,
	nugget=nugget,
	random_start=100)
	gp.fit(X, y)
	y2, MSE = gp.predict(x, eval_MSE=True)
	s2 = np.sqrt(MSE)
	return X, y, x, y2, s2

	# <codecell>

	X, y, x, y2, s2 = gpr(seed=0)
	plt.figure(1)
	pdense(x, y2, s2, M=1000)
	plt.plot(X, y, 'r.')
	plt.plot(x, y2, 'b:')
	a = plt.gca()
	a.set_ylim(-10, 15)
	plt.xlabel('$x$')
	plt.ylabel('$f(x)$')
	plt.show()

	# <codecell>

	# Run the experiment many times
	N = 200
	Y = np.nan * np.ones((N, len(x)))
	s = np.nan * np.ones((N, len(x)))
	print 'Running trial',
	for i in xrange(N):
	X, y, x, y2, s2 = gpr(seed=i)
	Y[i,:] = y2
	s[i,:] = s2
	print i,
	print '\nDone!'
	plt.plot(x, Y.T, 'b', alpha=0.15)
	a = plt.gca()
	a.set_ylim(-10, 15)
	plt.title('Bootstrap spaghetti plot')
	plt.xlabel('$x$')
	plt.ylabel('$f(x)$')
	plt.show()

	# <codecell>

	ymin, ymax = -10, 15
	bin_width = 0.15
	y_bins = np.arange(ymin, ymax, bin_width)
	H = np.zeros((len(y_bins)-1, len(x)))
	m = np.zeros(x.shape)
	for i in xrange(len(x)):
	h, e = np.histogram(Y[:,i], bins=np.arange(ymin, ymax, bin_width), density=True)
	H[:,i] = h
	m[i] = np.median(Y[:,i])
	hb = ndimage.gaussian_filter(H, sigma=1)
	plt.imshow(-hb, cmap='gray', aspect='auto', origin='lower',
	extent=(min(x)[0], max(x)[0], ymin, ymax))
	plt.plot(x, m, 'b:')
	a = plt.gca()
	a.set_ylim(-10, 15)
	plt.title('Bootstrap density plot')
	plt.xlabel('$x$')
	plt.ylabel('$f(x)$')

	# <codecell>