# -*- coding: utf-8 -*-
"""
Spline and other smoother classes for Generalized Additive Models
Author: Luca Puggini
Author: Josef Perktold
Created on Fri Jun 5 16:32:00 2015
"""
# import useful only for development
from abc import ABCMeta, abstractmethod
from statsmodels.compat.python import with_metaclass
import numpy as np
import pandas as pd
from patsy import dmatrix
from patsy.mgcv_cubic_splines import _get_all_sorted_knots
from statsmodels.tools.linalg import transf_constraints
# Obtain b splines from patsy
def _equally_spaced_knots(x, df):
n_knots = df - 2
x_min = x.min()
x_max = x.max()
knots = np.linspace(x_min, x_max, n_knots)
return knots
def _R_compat_quantile(x, probs):
# return np.percentile(x, 100 * np.asarray(probs))
probs = np.asarray(probs)
quantiles = np.asarray([np.percentile(x, 100 * prob)
for prob in probs.ravel(order="C")])
return quantiles.reshape(probs.shape, order="C")
# FIXME: is this copy/pasted? If so, why do we need it? If not, get
# rid of the try/except for scipy import
# from patsy splines.py
def _eval_bspline_basis(x, knots, degree, deriv='all', include_intercept=True):
try:
from scipy.interpolate import splev
except ImportError:
raise ImportError("spline functionality requires scipy")
# 'knots' are assumed to be already pre-processed. E.g. usually you
# want to include duplicate copies of boundary knots; you should do
# that *before* calling this constructor.
knots = np.atleast_1d(np.asarray(knots, dtype=float))
assert knots.ndim == 1
knots.sort()
degree = int(degree)
x = np.atleast_1d(x)
if x.ndim == 2 and x.shape[1] == 1:
x = x[:, 0]
assert x.ndim == 1
# XX FIXME: when points fall outside of the boundaries, splev and R seem
# to handle them differently. I do not know why yet. So until we understand
# this and decide what to do with it, I'm going to play it safe and
# disallow such points.
if np.min(x) < np.min(knots) or np.max(x) > np.max(knots):
raise NotImplementedError("some data points fall outside the "
"outermost knots, and I'm not sure how "
"to handle them. (Patches accepted!)")
# Thanks to Charles Harris for explaining splev. It's not well
# documented, but basically it computes an arbitrary b-spline basis
# given knots and degree on some specificed points (or derivatives
# thereof, but we do not use that functionality), and then returns some
# linear combination of these basis functions. To get out the basis
# functions themselves, we use linear combinations like [1, 0, 0], [0,
# 1, 0], [0, 0, 1].
# NB: This probably makes it rather inefficient (though I have not checked
# to be sure -- maybe the fortran code actually skips computing the basis
# function for coefficients that are zero).
# Note: the order of a spline is the same as its degree + 1.
# Note: there are (len(knots) - order) basis functions.
k_const = 1 - int(include_intercept)
n_bases = len(knots) - (degree + 1) - k_const
if deriv in ['all', 0]:
basis = np.empty((x.shape[0], n_bases), dtype=float)
ret = basis
if deriv in ['all', 1]:
der1_basis = np.empty((x.shape[0], n_bases), dtype=float)
ret = der1_basis
if deriv in ['all', 2]:
der2_basis = np.empty((x.shape[0], n_bases), dtype=float)
ret = der2_basis
for i in range(n_bases):
coefs = np.zeros((n_bases + k_const,))
# we are skipping the first column of the basis to drop constant
coefs[i + k_const] = 1
ii = i
if deriv in ['all', 0]:
basis[:, ii] = splev(x, (knots, coefs, degree))
if deriv in ['all', 1]:
der1_basis[:, ii] = splev(x, (knots, coefs, degree), der=1)
if deriv in ['all', 2]:
der2_basis[:, ii] = splev(x, (knots, coefs, degree), der=2)
if deriv == 'all':
return basis, der1_basis, der2_basis
else:
return ret
def compute_all_knots(x, df, degree):
order = degree + 1
n_inner_knots = df - order
lower_bound = np.min(x)
upper_bound = np.max(x)
knot_quantiles = np.linspace(0, 1, n_inner_knots + 2)[1:-1]
inner_knots = _R_compat_quantile(x, knot_quantiles)
all_knots = np.concatenate(([lower_bound, upper_bound] * order,
inner_knots))
return all_knots, lower_bound, upper_bound, inner_knots
def make_bsplines_basis(x, df, degree):
''' make a spline basis for x '''
all_knots, _, _, _ = compute_all_knots(x, df, degree)
basis, der_basis, der2_basis = _eval_bspline_basis(x, all_knots, degree)
return basis, der_basis, der2_basis
def get_knots_bsplines(x=None, df=None, knots=None, degree=3,
spacing='quantile', lower_bound=None,
upper_bound=None, all_knots=None):
"""knots for use in B-splines
There are two main options for the knot placement
- quantile spacing with multiplicity of boundary knots
- equal spacing extended to boundary or exterior knots
The first corresponds to splines as used by patsy. the second is the
knot spacing for P-Splines.
"""
# based on patsy memorize_finish
if all_knots is not None:
return all_knots
x_min = x.min()
x_max = x.max()
if degree < 0:
raise ValueError("degree must be greater than 0 (not %r)"
% (degree,))
if int(degree) != degree:
raise ValueError("degree must be an integer (not %r)"
% (degree,))
# These are guaranteed to all be 1d vectors by the code above
# x = np.concatenate(tmp["xs"])
if df is None and knots is None:
raise ValueError("must specify either df or knots")
order = degree + 1
if df is not None:
n_inner_knots = df - order
if n_inner_knots < 0:
raise ValueError("df=%r is too small for degree=%r; must be >= %s"
% (df, degree,
# We know that n_inner_knots is negative;
# if df were that much larger, it would
# have been zero, and things would work.
df - n_inner_knots))
if knots is not None:
if len(knots) != n_inner_knots:
raise ValueError("df=%s with degree=%r implies %s knots, "
"but %s knots were provided"
% (df, degree,
n_inner_knots, len(knots)))
elif spacing == 'quantile':
# Need to compute inner knots
knot_quantiles = np.linspace(0, 1, n_inner_knots + 2)[1:-1]
inner_knots = _R_compat_quantile(x, knot_quantiles)
elif spacing == 'equal':
# Need to compute inner knots
grid = np.linspace(0, 1, n_inner_knots + 2)[1:-1]
inner_knots = x_min + grid * (x_max - x_min)
diff_knots = inner_knots[1] - inner_knots[0]
else:
raise ValueError("incorrect option for spacing")
if knots is not None:
inner_knots = knots
if lower_bound is None:
lower_bound = np.min(x)
if upper_bound is None:
upper_bound = np.max(x)
if lower_bound > upper_bound:
raise ValueError("lower_bound > upper_bound (%r > %r)"
% (lower_bound, upper_bound))
inner_knots = np.asarray(inner_knots)
if inner_knots.ndim > 1:
raise ValueError("knots must be 1 dimensional")
if np.any(inner_knots < lower_bound):
raise ValueError("some knot values (%s) fall below lower bound "
"(%r)"
% (inner_knots[inner_knots < lower_bound],
lower_bound))
if np.any(inner_knots > upper_bound):
raise ValueError("some knot values (%s) fall above upper bound "
"(%r)"
% (inner_knots[inner_knots > upper_bound],
upper_bound))
if spacing == "equal":
diffs = np.arange(1, order + 1) * diff_knots
lower_knots = inner_knots[0] - diffs[::-1]
upper_knots = inner_knots[-1] + diffs
all_knots = np.concatenate((lower_knots, inner_knots, upper_knots))
else:
all_knots = np.concatenate(([lower_bound, upper_bound] * order,
inner_knots))
all_knots.sort()
return all_knots
def _get_integration_points(knots, k_points=3):
"""add points to each subinterval defined by knots
inserts k_points between each two consecutive knots
"""
k_points = k_points + 1
knots = np.unique(knots)
dxi = np.arange(k_points) / k_points
dxk = np.diff(knots)
dx = dxk[:, None] * dxi
x = np.concatenate(((knots[:-1, None] + dx).ravel(), [knots[-1]]))
return x
def get_covder2(smoother, k_points=4, integration_points=None,
skip_ctransf=False, deriv=2):
"""
Approximate integral of cross product of second derivative of smoother
This uses scipy.integrate simps to compute an approximation to the
integral of the smoother derivative cross-product at knots plus k_points
in between knots.
"""
from scipy.integrate import simps
knots = smoother.knots
x = _get_integration_points(knots, k_points=3)
if integration_points is None:
d2 = smoother.transform(x, deriv=deriv, skip_ctransf=skip_ctransf)
else:
x = integration_points
covd2 = simps(d2[:, :, None] * d2[:, None, :], x, axis=0)
return covd2
# TODO: this function should be deleted
def make_poly_basis(x, degree, intercept=True):
'''
given a vector x returns poly=(1, x, x^2, ..., x^degree)
and its first and second derivative
'''
if intercept:
start = 0
else:
start = 1
nobs = len(x)
basis = np.zeros(shape=(nobs, degree + 1 - start))
der_basis = np.zeros(shape=(nobs, degree + 1 - start))
der2_basis = np.zeros(shape=(nobs, degree + 1 - start))
for i in range(start, degree + 1):
basis[:, i - start] = x ** i
der_basis[:, i - start] = i * x ** (i - 1)
der2_basis[:, i - start] = i * (i - 1) * x ** (i - 2)
return basis, der_basis, der2_basis
# TODO: try to include other kinds of splines from patsy
# x = np.linspace(0, 1, 30)
# df = 10
# degree = 3
# from patsy.mgcv_cubic_splines import cc, cr, te
# all_knots, lower, upper, inner = compute_all_knots(x, df, degree)
# result = cc(x, df=df, knots=all_knots, lower_bound=lower, upper_bound=upper,
# constraints=None)
#
# import matplotlib.pyplot as plt
#
# result = np.array(result)
# print(result.shape)
# plt.plot(result.T)
# plt.show()
class UnivariateGamSmoother(with_metaclass(ABCMeta)):
"""Base Class for single smooth component
"""
def __init__(self, x, constraints=None, variable_name='x'):
self.x = x
self.constraints = constraints
self.variable_name = variable_name
self.nobs, self.k_variables = len(x), 1
base4 = self._smooth_basis_for_single_variable()
if constraints == 'center':
constraints = base4[0].mean(0)[None, :]
if constraints is not None and not isinstance(constraints, str):
ctransf = transf_constraints(constraints)
self.ctransf = ctransf
else:
# subclasses might set ctransf directly
# only used if constraints is None
if not hasattr(self, 'ctransf'):
self.ctransf = None
self.basis, self.der_basis, self.der2_basis, self.cov_der2 = base4
if self.ctransf is not None:
ctransf = self.ctransf
# transform attributes that are not None
if base4[0] is not None:
self.basis = base4[0].dot(ctransf)
if base4[1] is not None:
self.der_basis = base4[1].dot(ctransf)
if base4[2] is not None:
self.der2_basis = base4[2].dot(ctransf)
if base4[3] is not None:
self.cov_der2 = ctransf.T.dot(base4[3]).dot(ctransf)
self.dim_basis = self.basis.shape[1]
self.col_names = [self.variable_name + "_s" + str(i)
for i in range(self.dim_basis)]
@abstractmethod
def _smooth_basis_for_single_variable(self):
return
class UnivariateGenericSmoother(UnivariateGamSmoother):
"""Generic single smooth component
"""
def __init__(self, x, basis, der_basis, der2_basis, cov_der2,
variable_name='x'):
self.basis = basis
self.der_basis = der_basis
self.der2_basis = der2_basis
self.cov_der2 = cov_der2
super(UnivariateGenericSmoother, self).__init__(
x, variable_name=variable_name)
def _smooth_basis_for_single_variable(self):
return self.basis, self.der_basis, self.der2_basis, self.cov_der2
class UnivariatePolynomialSmoother(UnivariateGamSmoother):
"""polynomial single smooth component
"""
def __init__(self, x, degree, variable_name='x'):
self.degree = degree
super(UnivariatePolynomialSmoother, self).__init__(
x, variable_name=variable_name)
def _smooth_basis_for_single_variable(self):
# TODO: unclear description
"""
given a vector x returns poly=(1, x, x^2, ..., x^degree)
and its first and second derivative
"""
basis = np.zeros(shape=(self.nobs, self.degree))
der_basis = np.zeros(shape=(self.nobs, self.degree))
der2_basis = np.zeros(shape=(self.nobs, self.degree))
for i in range(self.degree):
dg = i + 1
basis[:, i] = self.x ** dg
der_basis[:, i] = dg * self.x ** (dg - 1)
if dg > 1:
der2_basis[:, i] = dg * (dg - 1) * self.x ** (dg - 2)
else:
der2_basis[:, i] = 0
cov_der2 = np.dot(der2_basis.T, der2_basis)
return basis, der_basis, der2_basis, cov_der2
class UnivariateBSplines(UnivariateGamSmoother):
"""B-Spline single smooth component
This creates and holds the B-Spline basis function for one
component.
Parameters
----------
x : array, 1-D
underlying explanatory variable for smooth terms.
df : int
numer of basis functions or degrees of freedom
degree : int
degree of the spline
include_intercept : bool
If False, then the basis functions are transformed so that they
do not include a constant. This avoids perfect collinearity if
a constant or several components are included in the model.
constraints : {None, str, array}
Constraints are used to transform the basis functions to satisfy
those constraints.
`constraints = 'center'` applies a linear transform to remove the
constant and center the basis functions.
variable_name : {None, str}
The name for the underlying explanatory variable, x, used in for
creating the column and parameter names for the basis functions.
covder2_kwds : {None, dict}
options for computing the penalty matrix from the second derivative
of the spline.
knot_kwds : {None, list[dict]}
option for the knot selection.
By default knots are selected in the same way as in patsy, however the
number of knots is independent of keeping or removing the constant.
Interior knot selection is based on quantiles of the data and is the
same in patsy and mgcv. Boundary points are at the limits of the data
range.
The available options use with `get_knots_bsplines` are
- knots : None or array
interior knots
- spacing : 'quantile' or 'equal'
- lower_bound : None or float
location of lower boundary knots, all boundary knots are at the same
point
- upper_bound : None or float
location of upper boundary knots, all boundary knots are at the same
point
- all_knots : None or array
If all knots are provided, then those will be taken as given and
all other options will be ignored.
"""
def __init__(self, x, df, degree=3, include_intercept=False,
constraints=None, variable_name='x',
covder2_kwds=None, **knot_kwds):
self.degree = degree
self.df = df
self.include_intercept = include_intercept
self.knots = get_knots_bsplines(x, degree=degree, df=df, **knot_kwds)
self.covder2_kwds = (covder2_kwds if covder2_kwds is not None
else {})
super(UnivariateBSplines, self).__init__(
x, constraints=constraints, variable_name=variable_name)
def _smooth_basis_for_single_variable(self):
basis, der_basis, der2_basis = _eval_bspline_basis(
self.x, self.knots, self.degree,
include_intercept=self.include_intercept)
# cov_der2 = np.dot(der2_basis.T, der2_basis)
cov_der2 = get_covder2(self, skip_ctransf=True,
**self.covder2_kwds)
return basis, der_basis, der2_basis, cov_der2
def transform(self, x_new, deriv=0, skip_ctransf=False):
"""create the spline basis for new observations
The main use of this stateful transformation is for prediction
using the same specification of the spline basis.
Parameters
----------
x_new : array
observations of the underlying explanatory variable
deriv : int
which derivative of the spline basis to compute
This is an options for internal computation.
skip_ctransf : bool
whether to skip the constraint transform
This is an options for internal computation.
Returns
-------
basis : ndarray
design matrix for the spline basis for given ``x_new``
"""
if x_new is None:
x_new = self.x
exog = _eval_bspline_basis(x_new, self.knots, self.degree,
deriv=deriv,
include_intercept=self.include_intercept)
# ctransf does not exist yet when cov_der2 is computed
ctransf = getattr(self, 'ctransf', None)
if ctransf is not None and not skip_ctransf:
exog = exog.dot(self.ctransf)
return exog
class UnivariateCubicSplines(UnivariateGamSmoother):
"""Cubic Spline single smooth component
Cubic splines as described in the wood's book in chapter 3
"""
def __init__(self, x, df, constraints=None, transform='domain',
variable_name='x'):
self.degree = 3
self.df = df
self.transform_data_method = transform
self.x = x = self.transform_data(x, initialize=True)
self.knots = _equally_spaced_knots(x, df)
super(UnivariateCubicSplines, self).__init__(
x, constraints=constraints, variable_name=variable_name)
def transform_data(self, x, initialize=False):
tm = self.transform_data_method
if tm is None:
return x
if initialize is True:
if tm == 'domain':
self.domain_low = x.min(0)
self.domain_upp = x.max(0)
elif isinstance(tm, tuple):
self.domain_low = tm[0]
self.domain_upp = tm[1]
self.transform_data_method = 'domain'
else:
raise ValueError("transform should be None, 'domain' "
"or a tuple")
self.domain_diff = self.domain_upp - self.domain_low
if self.transform_data_method == 'domain':
x = (x - self.domain_low) / self.domain_diff
return x
else:
raise ValueError("incorrect transform_data_method")
def _smooth_basis_for_single_variable(self):
basis = self._splines_x()[:, :-1]
# demean except for constant, does not affect derivatives
if not self.constraints == 'none':
self.transf_mean = basis[:, 1:].mean(0)
basis[:, 1:] -= self.transf_mean
else:
self.transf_mean = np.zeros(basis.shape[1])
s = self._splines_s()[:-1, :-1]
if not self.constraints == 'none':
ctransf = np.diag(1/np.max(np.abs(basis), axis=0))
else:
ctransf = np.eye(basis.shape[1])
# use np.eye to avoid rescaling
# ctransf = np.eye(basis.shape[1])
if self.constraints == 'no-const':
ctransf = ctransf[1:]
self.ctransf = ctransf
return basis, None, None, s
def _rk(self, x, z):
p1 = ((z - 1 / 2) ** 2 - 1 / 12) * ((x - 1 / 2) ** 2 - 1 / 12) / 4
p2 = ((np.abs(z - x) - 1 / 2) ** 4 -
1 / 2 * (np.abs(z - x) - 1 / 2) ** 2 +
7 / 240) / 24.
return p1 - p2
def _splines_x(self, x=None):
if x is None:
x = self.x
n_columns = len(self.knots) + 2
nobs = x.shape[0]
basis = np.ones(shape=(nobs, n_columns))
basis[:, 1] = x
# for loop equivalent to outer(x, xk, fun=rk)
for i, xi in enumerate(x):
for j, xkj in enumerate(self.knots):
s_ij = self._rk(xi, xkj)
basis[i, j + 2] = s_ij
return basis
def _splines_s(self):
q = len(self.knots) + 2
s = np.zeros(shape=(q, q))
for i, x1 in enumerate(self.knots):
for j, x2 in enumerate(self.knots):
s[i + 2, j + 2] = self._rk(x1, x2)
return s
def transform(self, x_new):
x_new = self.transform_data(x_new, initialize=False)
exog = self._splines_x(x_new)
exog[:, 1:] -= self.transf_mean
if self.ctransf is not None:
exog = exog.dot(self.ctransf)
return exog
class UnivariateCubicCyclicSplines(UnivariateGamSmoother):
"""cyclic cubic regression spline single smooth component
This creates and holds the Cyclic CubicSpline basis function for one
component.
Parameters
----------
x : array, 1-D
underlying explanatory variable for smooth terms.
df : int
numer of basis functions or degrees of freedom
degree : int
degree of the spline
include_intercept : bool
If False, then the basis functions are transformed so that they
do not include a constant. This avoids perfect collinearity if
a constant or several components are included in the model.
constraints : {None, str, array}
Constraints are used to transform the basis functions to satisfy
those constraints.
`constraints = 'center'` applies a linear transform to remove the
constant and center the basis functions.
variable_name : None or str
The name for the underlying explanatory variable, x, used in for
creating the column and parameter names for the basis functions.
"""
def __init__(self, x, df, constraints=None, variable_name='x'):
self.degree = 3
self.df = df
self.x = x
self.knots = _equally_spaced_knots(x, df)
super(UnivariateCubicCyclicSplines, self).__init__(
x, constraints=constraints, variable_name=variable_name)
def _smooth_basis_for_single_variable(self):
basis = dmatrix("cc(x, df=" + str(self.df) + ") - 1", {"x": self.x})
self.design_info = basis.design_info
n_inner_knots = self.df - 2 + 1 # +n_constraints
# TODO: from CubicRegressionSplines class
all_knots = _get_all_sorted_knots(self.x, n_inner_knots=n_inner_knots,
inner_knots=None,
lower_bound=None, upper_bound=None)
b, d = self._get_b_and_d(all_knots)
s = self._get_s(b, d)
return basis, None, None, s
def _get_b_and_d(self, knots):
"""Returns mapping of cyclic cubic spline values to 2nd derivatives.
.. note:: See 'Generalized Additive Models', Simon N. Wood, 2006,
pp 146-147
Parameters
----------
knots : ndarray
The 1-d array knots used for cubic spline parametrization,
must be sorted in ascending order.
Returns
-------
b, d: ndarrays
arrays for mapping cyclic cubic spline values at knots to
second derivatives.
penalty matrix is equal to ``s = d.T.dot(b^-1).dot(d)``
"""
h = knots[1:] - knots[:-1]
n = knots.size - 1
# b and d are defined such that the penalty matrix is equivalent to:
# s = d.T.dot(b^-1).dot(d)
# reference in particular to pag 146 of Wood's book
b = np.zeros((n, n)) # the b matrix on page 146 of Wood's book
d = np.zeros((n, n)) # the d matrix on page 146 of Wood's book
b[0, 0] = (h[n - 1] + h[0]) / 3.
b[0, n - 1] = h[n - 1] / 6.
b[n - 1, 0] = h[n - 1] / 6.
d[0, 0] = -1. / h[0] - 1. / h[n - 1]
d[0, n - 1] = 1. / h[n - 1]
d[n - 1, 0] = 1. / h[n - 1]
for i in range(1, n):
b[i, i] = (h[i - 1] + h[i]) / 3.
b[i, i - 1] = h[i - 1] / 6.
b[i - 1, i] = h[i - 1] / 6.
d[i, i] = -1. / h[i - 1] - 1. / h[i]
d[i, i - 1] = 1. / h[i - 1]
d[i - 1, i] = 1. / h[i - 1]
return b, d
def _get_s(self, b, d):
return d.T.dot(np.linalg.inv(b)).dot(d)
def transform(self, x_new):
exog = dmatrix(self.design_info, {"x": x_new})
if self.ctransf is not None:
exog = exog.dot(self.ctransf)
return exog
class AdditiveGamSmoother(with_metaclass(ABCMeta)):
"""Base class for additive smooth components
"""
def __init__(self, x, variable_names=None, include_intercept=False,
**kwargs):
# get pandas names before using asarray
if isinstance(x, pd.DataFrame):
data_names = x.columns.tolist()
elif isinstance(x, pd.Series):
data_names = [x.name]
else:
data_names = None
x = np.asarray(x)
if x.ndim == 1:
self.x = x.copy()
self.x.shape = (len(x), 1)
else:
self.x = x
self.nobs, self.k_variables = self.x.shape
if isinstance(include_intercept, bool):
self.include_intercept = [include_intercept] * self.k_variables
else:
self.include_intercept = include_intercept
if variable_names is None:
if data_names is not None:
self.variable_names = data_names
else:
self.variable_names = ['x' + str(i)
for i in range(self.k_variables)]
else:
self.variable_names = variable_names
self.smoothers = self._make_smoothers_list()
self.basis = np.hstack(list(smoother.basis
for smoother in self.smoothers))
self.dim_basis = self.basis.shape[1]
self.penalty_matrices = [smoother.cov_der2
for smoother in self.smoothers]
self.col_names = []
for smoother in self.smoothers:
self.col_names.extend(smoother.col_names)
self.mask = []
last_column = 0
for smoother in self.smoothers:
mask = np.array([False] * self.dim_basis)
mask[last_column:smoother.dim_basis + last_column] = True
last_column = last_column + smoother.dim_basis
self.mask.append(mask)
@abstractmethod
def _make_smoothers_list(self):
pass
def transform(self, x_new):
"""create the spline basis for new observations
The main use of this stateful transformation is for prediction
using the same specification of the spline basis.
Parameters
----------
x_new: array
observations of the underlying explanatory variable
Returns
-------
basis : ndarray
design matrix for the spline basis for given ``x_new``.
"""
exog = np.hstack(list(self.smoothers[i].transform(x_new[:, i])
for i in range(self.k_variables)))
return exog
class GenericSmoothers(AdditiveGamSmoother):
"""generic class for additive smooth components for GAM
"""
def __init__(self, x, smoothers):
self.smoothers = smoothers
super(GenericSmoothers, self).__init__(x, variable_names=None)
def _make_smoothers_list(self):
return self.smoothers
class PolynomialSmoother(AdditiveGamSmoother):
"""additive polynomial components for GAM
"""
def __init__(self, x, degrees, variable_names=None):
self.degrees = degrees
super(PolynomialSmoother, self).__init__(x,
variable_names=variable_names)
def _make_smoothers_list(self):
smoothers = []
for v in range(self.k_variables):
uv_smoother = UnivariatePolynomialSmoother(
self.x[:, v],
degree=self.degrees[v],
variable_name=self.variable_names[v])
smoothers.append(uv_smoother)
return smoothers
[docs]class BSplines(AdditiveGamSmoother):
"""additive smooth components using B-Splines
This creates and holds the B-Spline basis function for several
components.
Parameters
----------
x : array_like, 1-D or 2-D
underlying explanatory variable for smooth terms.
If 2-dimensional, then observations should be in rows and
explanatory variables in columns.
df : int
numer of basis functions or degrees of freedom
degree : int
degree of the spline
include_intercept : bool
If False, then the basis functions are transformed so that they
do not include a constant. This avoids perfect collinearity if
a constant or several components are included in the model.
constraints : {None, str, array}
Constraints are used to transform the basis functions to satisfy
those constraints.
`constraints = 'center'` applies a linear transform to remove the
constant and center the basis functions.
variable_names : {list[str], None}
The names for the underlying explanatory variables, x used in for
creating the column and parameter names for the basis functions.
If ``x`` is a pandas object, then the names will be taken from it.
knot_kwds : None or list of dict
option for the knot selection.
By default knots are selected in the same way as in patsy, however the
number of knots is independent of keeping or removing the constant.
Interior knot selection is based on quantiles of the data and is the
same in patsy and mgcv. Boundary points are at the limits of the data
range.
The available options use with `get_knots_bsplines` are
- knots : None or array
interior knots
- spacing : 'quantile' or 'equal'
- lower_bound : None or float
location of lower boundary knots, all boundary knots are at the same
point
- upper_bound : None or float
location of upper boundary knots, all boundary knots are at the same
point
- all_knots : None or array
If all knots are provided, then those will be taken as given and
all other options will be ignored.
Attributes
----------
smoothers : list of univariate smooth component instances
basis : design matrix, array of spline bases columns for all components
penalty_matrices : list of penalty matrices, one for each smooth term
dim_basis : number of columns in the basis
k_variables : number of smooth components
col_names : created names for the basis columns
There are additional attributes about the specification of the splines
and some attributes mainly for internal use.
Notes
-----
A constant in the spline basis function can be removed in two different
ways.
The first is by dropping one basis column and normalizing the
remaining columns. This is obtained by the default
``include_intercept=False, constraints=None``
The second option is by using the centering transform which is a linear
transformation of all basis functions. As a consequence of the
transformation, the B-spline basis functions do not have locally bounded
support anymore. This is obtained ``constraints='center'``. In this case
``include_intercept`` will be automatically set to True to avoid
dropping an additional column.
"""
def __init__(self, x, df, degree, include_intercept=False,
constraints=None, variable_names=None, knot_kwds=None):
self.degrees = degree
self.dfs = df
self.knot_kwds = knot_kwds
# TODO: move attaching constraints to super call
self.constraints = constraints
if constraints == 'center':
include_intercept = True
super(BSplines, self).__init__(x, include_intercept=include_intercept,
variable_names=variable_names)
def _make_smoothers_list(self):
smoothers = []
for v in range(self.k_variables):
kwds = self.knot_kwds[v] if self.knot_kwds else {}
uv_smoother = UnivariateBSplines(
self.x[:, v],
df=self.dfs[v], degree=self.degrees[v],
include_intercept=self.include_intercept[v],
constraints=self.constraints,
variable_name=self.variable_names[v], **kwds)
smoothers.append(uv_smoother)
return smoothers
class CubicSplines(AdditiveGamSmoother):
"""additive smooth components using cubic splines as in Wood 2006.
Note, these splines do NOT use the same spline basis as
``Cubic Regression Splines``.
"""
def __init__(self, x, df, constraints='center', transform='domain',
variable_names=None):
self.dfs = df
self.constraints = constraints
self.transform = transform
super(CubicSplines, self).__init__(x, constraints=constraints,
variable_names=variable_names)
def _make_smoothers_list(self):
smoothers = []
for v in range(self.k_variables):
uv_smoother = UnivariateCubicSplines(
self.x[:, v], df=self.dfs[v],
constraints=self.constraints,
transform=self.transform,
variable_name=self.variable_names[v])
smoothers.append(uv_smoother)
return smoothers
[docs]class CyclicCubicSplines(AdditiveGamSmoother):
"""additive smooth components using cyclic cubic regression splines
This spline basis is the same as in patsy.
Parameters
----------
x : array_like, 1-D or 2-D
underlying explanatory variable for smooth terms.
If 2-dimensional, then observations should be in rows and
explanatory variables in columns.
df : int
numer of basis functions or degrees of freedom
constraints : {None, str, array}
Constraints are used to transform the basis functions to satisfy
those constraints.
variable_names : {list[str], None}
The names for the underlying explanatory variables, x used in for
creating the column and parameter names for the basis functions.
If ``x`` is a pandas object, then the names will be taken from it.
"""
def __init__(self, x, df, constraints=None, variable_names=None):
self.dfs = df
# TODO: move attaching constraints to super call
self.constraints = constraints
super(CyclicCubicSplines, self).__init__(x,
variable_names=variable_names)
def _make_smoothers_list(self):
smoothers = []
for v in range(self.k_variables):
uv_smoother = UnivariateCubicCyclicSplines(
self.x[:, v],
df=self.dfs[v], constraints=self.constraints,
variable_name=self.variable_names[v])
smoothers.append(uv_smoother)
return smoothers
# class CubicRegressionSplines(BaseCubicSplines):
# # TODO: this class is still not tested
#
# def __init__(self, x, df=10):
# import warnings
# warnings.warn("This class is still not tested and it is probably"
# " not working properly. "
# "I suggest to use another smoother", Warning)
#
# super(CubicRegressionSplines, self).__init__(x, df)
#
# self.basis = dmatrix("cc(x, df=" + str(df) + ") - 1", {"x": x})
# n_inner_knots = df - 2 + 1 # +n_constraints
# # TODO: ACcording to CubicRegressionSplines class this should be
# # n_inner_knots = df - 2
# all_knots = _get_all_sorted_knots(x, n_inner_knots=n_inner_knots,
# inner_knots=None,
# lower_bound=None, upper_bound=None)
#
# b, d = self._get_b_and_d(all_knots)
# self.s = self._get_s(b, d)
#
# self.dim_basis = self.basis.shape[1]
#
# def _get_b_and_d(self, knots):
#
# h = knots[1:] - knots[:-1]
# n = knots.size - 1
#
# # b and d are defined such that the penalty matrix is equivalent to:
# # s = d.T.dot(b^-1).dot(d)
# # reference in particular to pag 146 of Wood's book
# b = np.zeros((n, n)) # the b matrix on page 146 of Wood's book
# d = np.zeros((n, n)) # the d matrix on page 146 of Wood's book
#
# for i in range(n-2):
# d[i, i] = 1/h[i]
# d[i, i+1] = -1/h[i] - 1/h[i+1]
# d[i, i+2] = 1/h[i+1]
#
# b[i, i] = (h[i] + h[i+1])/3
#
# for i in range(n-3):
# b[i, i+1] = h[i+1]/6
# b[i+1, i] = h[i+1]/6
#
# return b, d
#
# def _get_s(self, b, d):
#
# return d.T.dot(np.linalg.pinv(b)).dot(d)