Title: | Tests for Normality |
Version: | 1.0-4 |
Date: | 2015-07-29 |
Description: | Five omnibus tests for testing the composite hypothesis of normality. |
License: | GPL-2 | GPL-3 [expanded from: GPL (≥ 2)] |
Imports: | stats |
Packaged: | 2015-07-29 21:51:34 UTC; ligges |
Author: | Juergen Gross [aut], Uwe Ligges [aut, cre] |
Maintainer: | Uwe Ligges <ligges@statistik.tu-dortmund.de> |
NeedsCompilation: | no |
Repository: | CRAN |
Date/Publication: | 2015-07-30 00:14:57 |
Anderson-Darling test for normality
Description
Performs the Anderson-Darling test for the composite hypothesis of normality, see e.g. Thode (2002, Sec. 5.1.4).
Usage
ad.test(x)
Arguments
x |
a numeric vector of data values, the number of which must be greater than 7. Missing values are allowed. |
Details
The Anderson-Darling test is an EDF omnibus test for the composite hypothesis of normality. The test statistic is
A = -n -\frac{1}{n} \sum_{i=1}^{n} [2i-1]
[\ln(p_{(i)}) + \ln(1 - p_{(n-i+1)})],
where p_{(i)} = \Phi([x_{(i)} - \overline{x}]/s)
. Here,
\Phi
is the cumulative distribution function
of the standard normal distribution, and \overline{x}
and s
are mean and standard deviation of the data values.
The p-value is computed from the modified statistic
Z=A (1.0 + 0.75/n +2.25/n^{2})
\ according to Table 4.9 in
Stephens (1986).
Value
A list with class “htest” containing the following components:
statistic |
the value of the Anderson-Darling statistic. |
p.value |
the p-value for the test. |
method |
the character string “Anderson-Darling normality test”. |
data.name |
a character string giving the name(s) of the data. |
Note
The Anderson-Darling test is the recommended EDF test by Stephens (1986). Compared to the Cramer-von Mises test (as second choice) it gives more weight to the tails of the distribution.
Author(s)
Juergen Gross
References
Stephens, M.A. (1986): Tests based on EDF statistics. In: D'Agostino, R.B. and Stephens, M.A., eds.: Goodness-of-Fit Techniques. Marcel Dekker, New York.
Thode Jr., H.C. (2002): Testing for Normality. Marcel Dekker, New York.
See Also
shapiro.test
for performing the Shapiro-Wilk test for normality.
cvm.test
, lillie.test
,
pearson.test
, sf.test
for performing further tests for normality.
qqnorm
for producing a normal quantile-quantile plot.
Examples
ad.test(rnorm(100, mean = 5, sd = 3))
ad.test(runif(100, min = 2, max = 4))
Cramer-von Mises test for normality
Description
Performs the Cramer-von Mises test for the composite hypothesis of normality, see e.g. Thode (2002, Sec. 5.1.3).
Usage
cvm.test(x)
Arguments
x |
a numeric vector of data values, the number of which must be greater than 7. Missing values are allowed. |
Details
The Cramer-von Mises test is an EDF omnibus test for the composite hypothesis of normality. The test statistic is
W = \frac{1}{12 n} + \sum_{i=1}^{n} \left(p_{(i)} - \frac{2i-1}{2n}\right)^2,
where p_{(i)} = \Phi([x_{(i)} - \overline{x}]/s)
. Here,
\Phi
is the cumulative distribution function
of the standard normal distribution, and \overline{x}
and s
are mean and standard deviation of the data values.
The p-value is computed from the modified statistic
Z=W (1.0 + 0.5/n)
according to Table 4.9 in
Stephens (1986).
Value
A list with class “htest” containing the following components:
statistic |
the value of the Cramer-von Mises statistic. |
p.value |
the p-value for the test. |
method |
the character string “Cramer-von Mises normality test”. |
data.name |
a character string giving the name(s) of the data. |
Author(s)
Juergen Gross
References
Stephens, M.A. (1986): Tests based on EDF statistics. In: D'Agostino, R.B. and Stephens, M.A., eds.: Goodness-of-Fit Techniques. Marcel Dekker, New York.
Thode Jr., H.C. (2002): Testing for Normality. Marcel Dekker, New York.
See Also
shapiro.test
for performing the Shapiro-Wilk test for normality.
ad.test
, lillie.test
,
pearson.test
, sf.test
for performing further tests for normality.
qqnorm
for producing a normal quantile-quantile plot.
Examples
cvm.test(rnorm(100, mean = 5, sd = 3))
cvm.test(runif(100, min = 2, max = 4))
Lilliefors (Kolmogorov-Smirnov) test for normality
Description
Performs the Lilliefors (Kolmogorov-Smirnov) test for the composite hypothesis of normality, see e.g. Thode (2002, Sec. 5.1.1).
Usage
lillie.test(x)
Arguments
x |
a numeric vector of data values, the number of which must be greater than 4. Missing values are allowed. |
Details
The Lilliefors (Kolmogorov-Smirnov) test is an EDF omnibus test for the composite
hypothesis of normality. The test statistic is the maximal absolute difference
between empirical and
hypothetical cumulative distribution function. It may be computed as
D=\max\{D^{+}, D^{-}\}
with
D^{+} = \max_{i=1,\ldots, n}\{i/n - p_{(i)}\},
D^{-} = \max_{i=1,\ldots, n}\{p_{(i)} - (i-1)/n\},
where p_{(i)} = \Phi([x_{(i)} - \overline{x}]/s)
. Here,
\Phi
is the cumulative distribution function
of the standard normal distribution, and \overline{x}
and s
are mean and standard deviation of the data values.
The p-value is computed from the Dallal-Wilkinson (1986) formula, which is claimed to
be only reliable when the p-value is smaller than 0.1. If the Dallal-Wilkinson
p-value turns out to be greater than 0.1, then the p-value is computed from the distribution of
the modified statistic Z=D (\sqrt{n}-0.01+0.85/\sqrt{n})
, see Stephens (1974),
the actual p-value formula being obtained by a simulation and approximation process.
Value
A list with class “htest” containing the following components:
statistic |
the value of the Lilliefors (Kolomogorv-Smirnov) statistic. |
p.value |
the p-value for the test. |
method |
the character string “Lilliefors (Kolmogorov-Smirnov) normality test”. |
data.name |
a character string giving the name(s) of the data. |
Note
The Lilliefors (Kolomorov-Smirnov) test is the most famous EDF omnibus test for normality.
Compared to the Anderson-Darling test and the Cramer-von Mises test it is known to perform worse.
Although the test statistic obtained from lillie.test(x)
is the same as that obtained from
ks.test(x, "pnorm", mean(x), sd(x))
, it is not correct to use the p-value from the latter
for the composite hypothesis of normality (mean and variance unknown),
since the distribution of the test statistic is different when the parameters are estimated.
The function call lillie.test(x)
essentially produces
the same result as the S-PLUS function call ks.gof(x)
with the distinction that the p-value is not set to 0.5 when
the Dallal-Wilkinson approximation yields a p-value greater than 0.1. (Actually,
the alternative p-value approximation is provided for the complete range of test statistic values,
but is only used when the Dallal-Wilkinson approximation fails.)
Author(s)
Juergen Gross
References
Dallal, G.E. and Wilkinson, L. (1986): An analytic approximation to the distribution of Lilliefors' test for normality. The American Statistician, 40, 294–296.
Stephens, M.A. (1974): EDF statistics for goodness of fit and some comparisons. Journal of the American Statistical Association, 69, 730–737.
Thode Jr., H.C. (2002): Testing for Normality. Marcel Dekker, New York.
See Also
shapiro.test
for performing the Shapiro-Wilk test for normality.
ad.test
, cvm.test
,
pearson.test
, sf.test
for performing further tests for normality.
qqnorm
for producing a normal quantile-quantile plot.
Examples
lillie.test(rnorm(100, mean = 5, sd = 3))
lillie.test(runif(100, min = 2, max = 4))
Pearson chi-square test for normality
Description
Performs the Pearson chi-square test for the composite hypothesis of normality, see e.g. Thode (2002, Sec. 5.2).
Usage
pearson.test(x, n.classes = ceiling(2 * (n^(2/5))), adjust = TRUE)
Arguments
x |
a numeric vector of data values. Missing values are allowed. |
n.classes |
The number of classes. The default is due to Moore (1986). |
adjust |
logical; if |
Details
The Pearson test statistic is P=\sum (C_{i} - E_{i})^{2}/E_{i}
,
where C_{i}
is the number of counted and E_{i}
is the number of expected observations
(under the hypothesis) in class i
. The classes are build is such a way that they are equiprobable under the hypothesis
of normality. The p-value is computed from a chi-square distribution with n.classes
-3 degrees of freedom
if adjust
is TRUE
and from a chi-square distribution with n.classes
-1
degrees of freedom otherwise. In both cases this is not (!) the correct p-value,
lying somewhere between the two, see also Moore (1986).
Value
A list with class “htest” containing the following components:
statistic |
the value of the Pearson chi-square statistic. |
p.value |
the p-value for the test. |
method |
the character string “Pearson chi-square normality test”. |
data.name |
a character string giving the name(s) of the data. |
n.classes |
the number of classes used for the test. |
df |
the degress of freedom of the chi-square distribution used to compute the p-value. |
Note
The Pearson chi-square test is usually not recommended for testing the composite hypothesis of normality
due to its inferior power properties compared to other tests. It is common practice to compute the p-value
from the chi-square distribution with n.classes
- 3 degrees of freedom, in order to adjust for the
additional estimation of two parameters. (For the simple hypothesis of normality (mean and variance known)
the test statistic is asymptotically chi-square distributed with
n.classes
- 1 degrees of freedom.)
This is, however, not correct as long as the parameters are estimated by mean(x)
and var(x)
(or sd(x)
), as it is usually done, see Moore (1986) for details.
Since the true p-value is somewhere between the two, it is suggested to run pearson.test
twice, with
adjust = TRUE
(default) and with adjust = FALSE
.
It is also suggested to slightly change the default number of classes, in order
to see the effect on the p-value. Eventually, it is suggested not to rely upon the result of the test.
The function call pearson.test(x)
essentially produces
the same result as the S-PLUS function call chisq.gof((x-mean(x))/sqrt(var(x)), n.param.est=2)
.
Author(s)
Juergen Gross
References
Moore, D.S. (1986): Tests of the chi-squared type. In: D'Agostino, R.B. and Stephens, M.A., eds.: Goodness-of-Fit Techniques. Marcel Dekker, New York.
Thode Jr., H.C. (2002): Testing for Normality. Marcel Dekker, New York.
See Also
shapiro.test
for performing the Shapiro-Wilk test for normality.
ad.test
, cvm.test
,
lillie.test
, sf.test
for performing further tests for normality.
qqnorm
for producing a normal quantile-quantile plot.
Examples
pearson.test(rnorm(100, mean = 5, sd = 3))
pearson.test(runif(100, min = 2, max = 4))
Shapiro-Francia test for normality
Description
Performs the Shapiro-Francia test for the composite hypothesis of normality, see e.g. Thode (2002, Sec. 2.3.2).
Usage
sf.test(x)
Arguments
x |
a numeric vector of data values, the number of which must be between 5 and 5000. Missing values are allowed. |
Details
The test statistic of the Shapiro-Francia test is simply the squared correlation between the ordered sample values and the (approximated) expected ordered quantiles from the standard normal distribution. The p-value is computed from the formula given by Royston (1993).
Value
A list with class “htest” containing the following components:
statistic |
the value of the Shapiro-Francia statistic. |
p.value |
the p-value for the test. |
method |
the character string “Shapiro-Francia normality test”. |
data.name |
a character string giving the name(s) of the data. |
Note
The Shapiro-Francia test is known to perform well,
see also the comments by Royston (1993). The expected ordered quantiles
from the standard normal distribution are approximated by
qnorm(ppoints(x, a = 3/8))
, being slightly different from the approximation
qnorm(ppoints(x, a = 1/2))
used for the normal quantile-quantile plot by
qqnorm
for sample sizes greater than 10.
Author(s)
Juergen Gross
References
Royston, P. (1993): A pocket-calculator algorithm for the Shapiro-Francia test for non-normality: an application to medicine. Statistics in Medicine, 12, 181–184.
Thode Jr., H.C. (2002): Testing for Normality. Marcel Dekker, New York.
See Also
shapiro.test
for performing the Shapiro-Wilk test for normality.
ad.test
, cvm.test
,
lillie.test
, pearson.test
for performing further tests for normality.
qqnorm
for producing a normal quantile-quantile plot.
Examples
sf.test(rnorm(100, mean = 5, sd = 3))
sf.test(runif(100, min = 2, max = 4))