smd: Standardized mean difference

Description

Function to calculate the standardized mean difference (regular or unbiased) using either raw data or summary measures.

Usage

smd(Group.1 = NULL, Group.2 = NULL, Mean.1 = NULL, Mean.2 = NULL, 
s.1 = NULL, s.2 = NULL, s = NULL, n.1 = NULL, n.2 = NULL,
Unbiased=FALSE)

Value

Returns the estimated standardized mean difference.

Arguments

Group.1: Raw data for group 1.
Group.2: Raw data for group 2.
Mean.1: The mean of group 1.
Mean.2: The mean of group 2.
s.1: The standard deviation of group 1 (i.e., the square root of the unbiased estimator of the population variance).
s.2: The standard deviation of group 2 (i.e., the square root of the unbiased estimator of the population variance).
s: The pooled group standard deviation (i.e., the square root of the unbiased estimator of the population variance).
n.1: The sample size within group 1.
n.2: The sample size within group 2.
Unbiased: Returns the unbiased estimate of the standardized mean difference.

Author

Ken Kelley (University of Notre Dame; KKelley@ND.Edu)

Details

When Unbiased=TRUE, the unbiased estimate of the standardized mean difference is returned (Hedges, 1981).

References

Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Lawrence Erlbaum.

Cumming, G. & Finch, S. (2001). A primer on the understanding, use, and calculation of confidence intervals that are based on central and noncentral distributions, Educational and Psychological Measurement, 61, 532--574.

Hedges, L. V. (1981). Distribution theory for Glass's Estimator of effect size and related estimators. Journal of Educational Statistics, 2, 107--128.

Kelley, K. (2005) The effects of nonnormal distributions on confidence intervals around the standardized mean difference: Bootstrap and parametric confidence intervals, Educational and Psychological Measurement, 65, 51--69.

Kelley, K. (2007). Constructing confidence intervals for standardized effect sizes: Theory, application, and implementation. Journal of Statistical Software, 20 (8), 1--24.

Steiger, J. H., & Fouladi, R. T. (1997). Noncentrality interval estimation and the evaluation of statistical methods. In L. L. Harlow, S. A. Mulaik, & J. H. Steiger (Eds.), What if there were no significance tests? (pp. 221--257). Mahwah, NJ: Lawrence Erlbaum.

Examples

Run this code

# Generate sample data.
set.seed(113)
g.1 <- rnorm(n=25, mean=.5, sd=1)
g.2 <- rnorm(n=25, mean=0, sd=1)
smd(Group.1=g.1, Group.2=g.2)

M.x <- .66745
M.y <- .24878
sd <- 1.048
smd(Mean.1=M.x, Mean.2=M.y, s=sd)

M.x <- .66745
M.y <- .24878
n1 <- 25
n2 <- 25
sd.1 <- .95817
sd.2 <- 1.1311
smd(Mean.1=M.x, Mean.2=M.y, s.1=sd.1, s.2=sd.2, n.1=n1, n.2=n2)

smd(Mean.1=M.x, Mean.2=M.y, s.1=sd.1, s.2=sd.2, n.1=n1, n.2=n2, 
Unbiased=TRUE)

Run the code above in your browser using DataLab