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RKHS inner product #550

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19 changes: 19 additions & 0 deletions docs/refs.bib
Original file line number Diff line number Diff line change
Expand Up @@ -31,6 +31,14 @@ @article{baillo+grane_2009_local
keywords = {62G08,62G30,Cross-validation,Fourier expansion,Functional data,Kernel regression,Local linear regression,Nonparametric smoothing}
}

@book{berlinet+thomas-agnan_2011_reproducing,
title={Reproducing kernel Hilbert spaces in probability and statistics},
author={Berlinet, Alain and Thomas-Agnan, Christine},
year={2011},
publisher={Springer Science \& Business Media}
}


@article{berrendero++_2016_mrmr,
title = {The {{mRMR}} Variable Selection Method: A Comparative Study for Functional Data},
shorttitle = {The {{mRMR}} Variable Selection Method},
Expand Down Expand Up @@ -293,6 +301,17 @@ @article{ghosh+chaudhuri_2005_maximum
keywords = {Bayes risk,cross-validation,data depth,elliptic symmetry,kernel density estimation,location shift model,Mahalanobis distance,misclassification rate,Vapnik Chervonenkis dimension}
}

@article{gutierrez++_1992_numerical,
title={On the numerical expansion of a second order stochastic process},
author={Guti{\'e}rrez, Ram{\'o}n and Ruiz, Juan Carlos and Valderrama, Mariano J},
journal={Applied stochastic models and data analysis},
volume={8},
number={2},
pages={67--77},
year={1992},
publisher={Wiley Online Library}
}

@article{li++_2012_ddclassifier,
title = {{{DD-Classifier}}: {{Nonparametric}} Classification Procedure Based on {{DD-Plot}}},
shorttitle = {{{DD-Classifier}}},
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194 changes: 194 additions & 0 deletions examples/plot_rkhs_inner_product.py
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@@ -0,0 +1,194 @@
"""
Reproducing Kernel Hilbert Space Inner Product for the Brownian Bridge
=======================================================================

This example shows how to compute the inner product of two functions in the
reproducing kernel Hilbert space (RKHS) of the Brownian Bridge.
"""

# Author: Martín Sánchez Signorini
# License: MIT

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
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from skfda.misc.rkhs_product import rkhs_inner_product
from skfda.representation import FDataGrid
from skfda.typing._numpy import NDArrayFloat

###############################################################################
# The kernel corresponding to a Brownian Bridge process
# :footcite:p:`gutierrez++_1992_numerical` in the interval :math:`[0, 1]` is
#
# .. math::
# k(s, t) = \min(s, t) - st
#
# The RKHS inner product method
# :func:`~skfda.misc.rkhs_product.rkhs_inner_product` requires the kernel to
# be defined as a function of two vector arguments that returns the matrix of
# values of the kernel in the corresponding grid.
# The following function defines the kernel as such a function.


def brownian_bridge_covariance(
t: NDArrayFloat,
s: NDArrayFloat,
) -> NDArrayFloat:
"""
Covariance function of the Brownian Bridge process.

This function must receive two vectors of points while returning the
matrix of values of the covariance function in the corresponding grid.
"""
t_col = t[:, None]
s_row = s[None, :]
return np.minimum(t_col, s_row) - t_col * s_row


###############################################################################
# The RKHS of this kernel :footcite:p:`berlinet+thomas-agnan_2011_reproducing`
# is the set of functions
#
# .. math::
# f: [0, 1] \to \mathbb{R} \quad \text{ such that }
# f \text{ is absolutely continuous, }
# f(0) = f(1) = 0 \text{ and }
# f' \in L^2([0, 1]).
#
# For this example we will be using the following functions in this RKHS:
#
# .. math::
# \begin{align}
# f(t) &= 1 - (2t - 1)^2 \\
# g(t) &= \sin(\pi t)
# \end{align}
#
# The following code defines a method to compute the inner product of these
# two functions in the RKHS of the Brownian Bridge, using a variable number of
# points of discretization of the functions.

def brownian_bridge_rkhs_inner_product(
num_points: int,
) -> float:
"""Inner product of two functions in the RKHS of the Brownian Bridge."""
# Define the functions
# Remove first and last points to avoid a singular covariance matrix
grid_points = np.linspace(0, 1, num_points + 2)[1:-1]
f = FDataGrid(
[1 - (2 * grid_points - 1)**2],
grid_points,
)
g = FDataGrid(
[np.sin(np.pi * grid_points)],
grid_points,
)

# Compute the inner product
return rkhs_inner_product( # type: ignore[no-any-return]
fdata1=f,
fdata2=g,
cov_function=brownian_bridge_covariance,
)[0]


# Plot the functions f and g in the same figure
FDataGrid(
np.concatenate(
[
1 - (2 * np.linspace(0, 1, 100) - 1)**2,
np.sin(np.pi * np.linspace(0, 1, 100)),
],
axis=0,
).reshape(2, 100),
np.linspace(0, 1, 100),
).plot()
plt.show()

###############################################################################
# The inner product of two functions :math:`f, g` in this RKHS
# :footcite:p:`berlinet+thomas-agnan_2011_reproducing` is
#
# .. math::
# \langle f, g \rangle = \int_0^1 f'(t) g'(t) dt.
#
# Therefore, the exact value of the product of these two functions in the RKHS
# of the Brownian Bridge can be explicitly calculated.
# First, we have that their derivatives are
#
# .. math::
# \begin{align}
# f'(t) &= 4(1 - 2t) \\
# g'(t) &= \pi \cos(\pi t)
# \end{align}
#
# Then, the inner product in :math:`L^2([0, 1])` of these derivatives is
#
# .. math::
# \begin{align}
# \langle f', g' \rangle &= \int_0^1 f'(t) g'(t) dt \\
# &= \int_0^1 4(1 - 2t) \pi \cos(\pi t) dt \\
# &= \frac{16}{\pi}.
# \end{align}
#
# Which is the exact value of their inner product in the RKHS of the Brownian
# Bridge.
# Thus, we measure the difference between the exact value and the value
# computed by the method :func:`~skfda.misc.rkhs_product.rkhs_inner_product`
# for increasing numbers of discretization points.
# In particular, we will be using from 500 to 10000 points with a step of 500.
#
# The following code computes the inner product for each number of points and
# plots the difference between the exact value and the computed value.

num_points_list = np.arange(
start=500,
stop=10001,
step=500,
)
expected_value = 16 / np.pi

errors_df = pd.DataFrame(
columns=["Number of points of discretization", "Absolute error"],
)

for num_points in num_points_list:
computed_value = brownian_bridge_rkhs_inner_product(num_points)
error = np.abs(computed_value - expected_value)

# Add new row to the dataframe
errors_df.loc[len(errors_df)] = [num_points, error]

# Plot the errors
errors_df.plot(
x="Number of points of discretization",
y="Absolute error",
title="Absolute error of the inner product",
xlabel="Number of points of discretization",
ylabel="Absolute error",
)
plt.show()


###############################################################################
# The following code plots the errors using a logarithmic scale in the y-axis.

errors_df.plot(
x="Number of points of discretization",
y="Absolute error",
title="Absolute error of the inner product",
xlabel="Number of points of discretization",
ylabel="Absolute error",
logy=True,
)
plt.show()

###############################################################################
# This example shows the convergence of the method
# :func:`~skfda.misc.rkhs_product.rkhs_inner_product` for the Brownian Bridge
# kernel, while also showing how to apply this method using a custom covariance
# function.

###############################################################################
# **References:**
# .. footbibliography::
2 changes: 2 additions & 0 deletions skfda/misc/covariances.py
Original file line number Diff line number Diff line change
Expand Up @@ -808,6 +808,8 @@ def __call__(self, x: ArrayLike, y: ArrayLike) -> NDArrayFloat:
Returns:
Covariance function evaluated at the grid formed by x and y.
"""
x = _transform_to_2d(x)
y = _transform_to_2d(y)
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return self.cov_fdata([x, y], grid=True)[0, ..., 0]


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