| OptSig.anova {OptSig} | R Documentation |
Optimal significance level calculation for balanced one-way analysis of variance tests
Description
Computes the optimal significance level for the test for balanced one-way analysis of variance tests
Usage
OptSig.anova(K = NULL, n = NULL, f = NULL, p = 0.5, k = 1, Figure = TRUE)
Arguments
K |
Number of groups |
n |
Number of observations (per group) |
f |
Effect size |
p |
prior probability for H0, default is p = 0.5 |
k |
relative loss from Type I and II errors, k = L2/L1, default is k = 1 |
Figure |
show graph if TRUE (default); No graph if FALSE |
Details
Refer to Kim and Choi (2020) for the details of k and p
For the value of f, refer to Cohen (1988) or Champely (2017)
Value
alpha.opt |
Optimal level of significance |
beta.opt |
Type II error probability at the optimal level |
Note
Also refer to the manual for the pwr package
The black curve in the figure is the line of enlightened judgement: see Kim and Choi (2020). The red dot inticates the optimal significance level that minimizes the expected loss: (alpha.opt,beta.opt). The blue horizontal line indicates the case of alpha = 0.05 as a reference point.
Author(s)
Jae H. Kim (using a function from the pwr package)
References
Kim and Choi, 2020, Choosing the Level of Significance: A Decision-theoretic Approach: Abacus: a Journal of Accounting, Finance and Business Studies. Wiley. <https://doi.org/10.1111/abac.12172>
Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale,NJ: Lawrence Erlbaum.
Stephane Champely (2017). pwr: Basic Functions for Power Analysis. R package version 1.2-1. https://CRAN.R-project.org/package=pwr
See Also
Kim, Jae H., 2020, Decision-theoretic hypothesis testing: A primer with R package OptSig, The American Statistician. <https://doi.org/10.1080/00031305.2020.1750484.>
Examples
OptSig.anova(f=0.28,K=4,n=20)