201 lines
5.8 KiB
Python
201 lines
5.8 KiB
Python
from __future__ import division, print_function, absolute_import
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import numpy as np
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from numpy.testing import (assert_equal, assert_array_equal,
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assert_array_almost_equal, assert_approx_equal, assert_allclose)
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from pytest import raises as assert_raises
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from scipy.special import xlogy
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from scipy.stats.contingency import margins, expected_freq, chi2_contingency
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def test_margins():
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a = np.array([1])
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m = margins(a)
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assert_equal(len(m), 1)
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m0 = m[0]
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assert_array_equal(m0, np.array([1]))
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a = np.array([[1]])
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m0, m1 = margins(a)
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expected0 = np.array([[1]])
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expected1 = np.array([[1]])
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assert_array_equal(m0, expected0)
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assert_array_equal(m1, expected1)
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a = np.arange(12).reshape(2, 6)
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m0, m1 = margins(a)
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expected0 = np.array([[15], [51]])
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expected1 = np.array([[6, 8, 10, 12, 14, 16]])
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assert_array_equal(m0, expected0)
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assert_array_equal(m1, expected1)
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a = np.arange(24).reshape(2, 3, 4)
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m0, m1, m2 = margins(a)
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expected0 = np.array([[[66]], [[210]]])
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expected1 = np.array([[[60], [92], [124]]])
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expected2 = np.array([[[60, 66, 72, 78]]])
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assert_array_equal(m0, expected0)
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assert_array_equal(m1, expected1)
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assert_array_equal(m2, expected2)
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def test_expected_freq():
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assert_array_equal(expected_freq([1]), np.array([1.0]))
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observed = np.array([[[2, 0], [0, 2]], [[0, 2], [2, 0]], [[1, 1], [1, 1]]])
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e = expected_freq(observed)
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assert_array_equal(e, np.ones_like(observed))
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observed = np.array([[10, 10, 20], [20, 20, 20]])
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e = expected_freq(observed)
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correct = np.array([[12., 12., 16.], [18., 18., 24.]])
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assert_array_almost_equal(e, correct)
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def test_chi2_contingency_trivial():
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# Some very simple tests for chi2_contingency.
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# A trivial case
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obs = np.array([[1, 2], [1, 2]])
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chi2, p, dof, expected = chi2_contingency(obs, correction=False)
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assert_equal(chi2, 0.0)
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assert_equal(p, 1.0)
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assert_equal(dof, 1)
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assert_array_equal(obs, expected)
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# A *really* trivial case: 1-D data.
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obs = np.array([1, 2, 3])
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chi2, p, dof, expected = chi2_contingency(obs, correction=False)
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assert_equal(chi2, 0.0)
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assert_equal(p, 1.0)
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assert_equal(dof, 0)
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assert_array_equal(obs, expected)
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def test_chi2_contingency_R():
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# Some test cases that were computed independently, using R.
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Rcode = \
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"""
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# Data vector.
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data <- c(
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12, 34, 23, 4, 47, 11,
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35, 31, 11, 34, 10, 18,
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12, 32, 9, 18, 13, 19,
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12, 12, 14, 9, 33, 25
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)
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# Create factor tags:r=rows, c=columns, t=tiers
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r <- factor(gl(4, 2*3, 2*3*4, labels=c("r1", "r2", "r3", "r4")))
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c <- factor(gl(3, 1, 2*3*4, labels=c("c1", "c2", "c3")))
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t <- factor(gl(2, 3, 2*3*4, labels=c("t1", "t2")))
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# 3-way Chi squared test of independence
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s = summary(xtabs(data~r+c+t))
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print(s)
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"""
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Routput = \
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"""
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Call: xtabs(formula = data ~ r + c + t)
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Number of cases in table: 478
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Number of factors: 3
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Test for independence of all factors:
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Chisq = 102.17, df = 17, p-value = 3.514e-14
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"""
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obs = np.array(
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[[[12, 34, 23],
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[35, 31, 11],
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[12, 32, 9],
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[12, 12, 14]],
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[[4, 47, 11],
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[34, 10, 18],
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[18, 13, 19],
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[9, 33, 25]]])
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chi2, p, dof, expected = chi2_contingency(obs)
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assert_approx_equal(chi2, 102.17, significant=5)
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assert_approx_equal(p, 3.514e-14, significant=4)
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assert_equal(dof, 17)
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Rcode = \
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"""
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# Data vector.
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data <- c(
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#
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12, 17,
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11, 16,
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#
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11, 12,
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15, 16,
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#
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23, 15,
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30, 22,
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#
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14, 17,
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15, 16
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)
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# Create factor tags:r=rows, c=columns, d=depths(?), t=tiers
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r <- factor(gl(2, 2, 2*2*2*2, labels=c("r1", "r2")))
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c <- factor(gl(2, 1, 2*2*2*2, labels=c("c1", "c2")))
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d <- factor(gl(2, 4, 2*2*2*2, labels=c("d1", "d2")))
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t <- factor(gl(2, 8, 2*2*2*2, labels=c("t1", "t2")))
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# 4-way Chi squared test of independence
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s = summary(xtabs(data~r+c+d+t))
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print(s)
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"""
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Routput = \
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"""
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Call: xtabs(formula = data ~ r + c + d + t)
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Number of cases in table: 262
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Number of factors: 4
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Test for independence of all factors:
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Chisq = 8.758, df = 11, p-value = 0.6442
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"""
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obs = np.array(
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[[[[12, 17],
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[11, 16]],
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[[11, 12],
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[15, 16]]],
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[[[23, 15],
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[30, 22]],
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[[14, 17],
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[15, 16]]]])
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chi2, p, dof, expected = chi2_contingency(obs)
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assert_approx_equal(chi2, 8.758, significant=4)
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assert_approx_equal(p, 0.6442, significant=4)
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assert_equal(dof, 11)
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def test_chi2_contingency_g():
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c = np.array([[15, 60], [15, 90]])
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g, p, dof, e = chi2_contingency(c, lambda_='log-likelihood', correction=False)
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assert_allclose(g, 2*xlogy(c, c/e).sum())
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g, p, dof, e = chi2_contingency(c, lambda_='log-likelihood', correction=True)
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c_corr = c + np.array([[-0.5, 0.5], [0.5, -0.5]])
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assert_allclose(g, 2*xlogy(c_corr, c_corr/e).sum())
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c = np.array([[10, 12, 10], [12, 10, 10]])
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g, p, dof, e = chi2_contingency(c, lambda_='log-likelihood')
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assert_allclose(g, 2*xlogy(c, c/e).sum())
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def test_chi2_contingency_bad_args():
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# Test that "bad" inputs raise a ValueError.
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# Negative value in the array of observed frequencies.
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obs = np.array([[-1, 10], [1, 2]])
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assert_raises(ValueError, chi2_contingency, obs)
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# The zeros in this will result in zeros in the array
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# of expected frequencies.
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obs = np.array([[0, 1], [0, 1]])
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assert_raises(ValueError, chi2_contingency, obs)
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# A degenerate case: `observed` has size 0.
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obs = np.empty((0, 8))
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assert_raises(ValueError, chi2_contingency, obs)
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