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The POWER Procedure: Analyses in the ONESAMPLEMEANS Statement :: SAS/STAT(R) 9.2 User's Guide, Second Edition
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Analyses in the ONESAMPLEMEANS Statement
One­Sample t Test (TEST=T)
The hypotheses for the one­sample test are
The test assumes normally distributed data and requires
where
. The test statistics are
is the sample mean, is the sample standard deviation, and
The test is
Exact power computations for tests are discussed in O’Brien and Muller (1993, Section 8.2), although not
specifically for the one­sample case. The power is based on the noncentral and distributions:
Solutions for , , and are obtained by numerically inverting the power equation. Closed­form solutions for other
parameters, in terms of , are as follows:
One­Sample t Test with Lognormal Data (TEST=T DIST=LOGNORMAL)
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The lognormal case is handled by reexpressing the analysis equivalently as a normality­based test on the log­
transformed data, by using properties of the lognormal distribution as discussed in Johnson, Kotz, and Balakrishnan
(1994, Chapter 14). The approaches in the section One­Sample t Test (TEST=T) then apply.
In contrast to the usual test on normal data, the hypotheses with lognormal data are defined in terms of geometric
means rather than arithmetic means. This is because the transformation of a null arithmetic mean of lognormal data
to the normal scale depends on the unknown coefficient of variation, resulting in an ill­defined hypothesis on the log­
transformed data. Geometric means transform cleanly and are more natural for lognormal data.
The hypotheses for the one­sample test with lognormal data are
Let
and
be the (arithmetic) mean and standard deviation of the normal distribution of the log­transformed data.
The hypotheses can be rewritten as follows:
where
.
The test assumes lognormally distributed data and requires
.
The power is
where
Equivalence Test for Mean of Normal Data (TEST=EQUIV DIST=NORMAL)
The hypotheses for the equivalence test are
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The analysis is the two one­sided tests (TOST) procedure of Schuirmann (1987). The test assumes normally
distributed data and requires
. Phillips (1990) derives an expression for the exact power assuming a two­
sample balanced design; the results are easily adapted to a one­sample design:
where
is Owen’s Q function, defined in the section Common Notation.
Equivalence Test for Mean of Lognormal Data (TEST=EQUIV DIST=LOGNORMAL)
The lognormal case is handled by reexpressing the analysis equivalently as a normality­based test on the log­
transformed data, by using properties of the lognormal distribution as discussed in Johnson, Kotz, and Balakrishnan
(1994, Chapter 14). The approaches in the section Equivalence Test for Mean of Normal Data (TEST=EQUIV
DIST=NORMAL) then apply.
In contrast to the additive equivalence test on normal data, the hypotheses with lognormal data are defined in terms
of geometric means rather than arithmetic means. This is because the transformation of an arithmetic mean of
lognormal data to the normal scale depends on the unknown coefficient of variation, resulting in an ill­defined
hypothesis on the log­transformed data. Geometric means transform cleanly and are more natural for lognormal
data.
The hypotheses for the equivalence test are
The analysis is the two one­sided tests (TOST) procedure of Schuirmann (1987) on the log­transformed data. The
test assumes lognormally distributed data and requires
. Diletti, Hauschke, and Steinijans (1991) derive an
expression for the exact power assuming a crossover design; the results are easily adapted to a one­sample
design:
where
is the standard deviation of the log­transformed data, and
Common Notation.
is Owen’s Q function, defined in the section
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Confidence Interval for Mean (CI=T)
This analysis of precision applies to the standard ­based confidence interval:
where is the sample mean and is the sample standard deviation. The "half­width" is defined as the distance
from the point estimate to a finite endpoint,
A "valid" conference interval captures the true mean. The exact probability of obtaining at most the target
confidence interval half­width , unconditional or conditional on validity, is given by Beal (1989):
where
and
is Owen’s Q function, defined in the section Common Notation.
A "quality" confidence interval is both sufficiently narrow (half­width
) and valid:
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