Estimates k-factors for tolerance intervals based on normality.
K.factor(n, f = NULL, alpha = 0.05, P = 0.99, side = 1,
method = c("HE", "HE2", "WBE", "ELL", "KM", "EXACT",
"OCT"), m = 50)
K.factor
returns the k-factor for tolerance intervals based on normality with the arguments specified above.
The (effective) sample size.
The number of degrees of freedom associated with calculating the estimate of the population standard deviation.
If NULL
, then f
is taken to be n-1
.
The level chosen such that 1-alpha
is the confidence level.
The proportion of the population to be covered by the tolerance interval.
Whether a 1-sided or 2-sided tolerance interval is required (determined by side = 1
or side = 2
,
respectively).
The method for calculating the k-factors. The k-factor for the 1-sided tolerance intervals
is performed exactly and thus is the same for the chosen method. "HE"
is the
Howe method and is often viewed as being extremely accurate, even for small sample sizes. "HE2"
is a second method due to Howe, which performs similarly to the Weissberg-Beatty method, but is computationally simpler. "WBE"
is the
Weissberg-Beatty method (also called the Wald-Wolfowitz method), which performs similarly to the first Howe method for larger sample sizes. "ELL"
is
the Ellison correction to the Weissberg-Beatty method when f
is appreciably larger than n^2
. A warning
message is displayed if f
is not larger than n^2
. "KM"
is the Krishnamoorthy-Mathew approximation to the exact solution, which works well for larger sample sizes. "EXACT"
computes the
k-factor exactly by finding the integral solution to the problem via the integrate
function. Note the computation time of this method is largely determined by m
. "OCT"
is the Owen approach
to compute the k-factor when controlling the tails so that there is not more than (1-P)/2 of the data in each tail of the distribution.
The maximum number of subintervals to be used in the integrate
function. This is necessary only for method = "EXACT"
and method = "OCT"
. The larger
the number, the more accurate the solution. Too low of a value can result in an error. A large value can also cause the function to be slow for method = "EXACT"
.
Ellison, B. E. (1964), On Two-Sided Tolerance Intervals for a Normal Distribution, Annals of Mathematical Statistics, 35, 762--772.
Howe, W. G. (1969), Two-Sided Tolerance Limits for Normal Populations - Some Improvements, Journal of the American Statistical Association, 64, 610--620.
Krishnamoorthy, K. and Mathew, T. (2009), Statistical Tolerance Regions: Theory, Applications, and Computation, Wiley.
Odeh, R. E. and Owen, D. B. (1980), Tables for Normal Tolerance Limits, Sampling Plans, and Screening, Marcel-Dekker.
Owen, D. B. (1964), Controls of Percentages in Both Tails of the Normal Distribution, Technometrics, 6, 377-387.
Wald, A. and Wolfowitz, J. (1946), Tolerance Limits for a Normal Distribution, Annals of the Mathematical Statistics, 17, 208--215.
Weissberg, A. and Beatty, G. (1969), Tables of Tolerance Limit Factors for Normal Distributions, Technometrics, 2, 483--500.
## Showing the k-factor under the Howe, Weissberg-Beatty,
## and exact estimation methods.
K.factor(10, P = 0.95, side = 2, method = "HE")
K.factor(10, P = 0.95, side = 2, method = "WBE")
K.factor(10, P = 0.95, side = 2, method = "EXACT", m = 20)
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