Standardized mean of a contrast variable explained

In statistics, the standardized mean of a contrast variable (SMCV or SMC), is a parameter assessing effect size. The SMCV is defined as mean divided by the standard deviation of a contrast variable.^{[1] [2]} The SMCV was first proposed for one-way ANOVA cases ^[2] and was then extended to multi-factor ANOVA cases.^[3]

Background

Consistent interpretations for the strength of group comparison, as represented by a contrast, are important.^{[4] [5]}

When there are only two groups involved in a comparison, SMCV is the same as the strictly standardized mean difference (SSMD). SSMD belongs to a popular type of effect-size measure called "standardized mean differences"^[6] which includes Cohen's

^[7] and Glass's ^[8]

In ANOVA, a similar parameter for measuring the strength of group comparison is standardized effect size (SES).^[9] One issue with SES is that its values are incomparable for contrasts with different coefficients. SMCV does not have such an issue.

Concept

Suppose the random values in t groups represented by random variables

have means and variances , respectively. A contrast variable is defined by where the 's are a set of coefficients representing a comparison of interest and satisfy . The SMCV of contrast variable , denoted by , is defined as^[1] } = \frac

where

is the covariance of and . When are independent, }.

Classifying rule for the strength of group comparisons

The population value (denoted by

) of SMCV can be used to classify the strength of a comparison represented by a contrast variable, as shown in the following table.^{[1] [2]} This classifying rule has a probabilistic basis due to the link between SMCV and c⁺-probability.^[1]

Effect type	Effect subtype	Thresholds for negative SMCV	Thresholds for positive SMCV
Extra large	Extremely strong	λ\le-5	λ\ge5
	Very strong	-5<λ\le-3	5>λ\ge3
	Strong	-3<λ\le-2	3>λ\ge2
	Fairly strong	-2<λ\le-1.645	2>λ\ge1.645
Large	Moderate	-1.645<λ\le-1.28	1.645>λ\ge1.28
	Fairly moderate	-1.28<λ\le-1	1.28>λ\ge1
Medium	Fairly weak	-1<λ\le-0.75	1>λ\ge0.75
	Weak	-0.75<λ<-0.5	0.75>λ>0.5
	Very weak	-0.5\leλ<-0.25	0.5\geλ>0.25
Small	Extremely weak	-0.25\leλ<0	0.25\geλ>0
	No effect	λ=0

Statistical estimation and inference

The estimation and inference of SMCV presented below is for one-factor experiments.^{[1] [2]} Estimation and inference of SMCV for multi-factor experiments has also been discussed.^{[1] [3]}

The estimation of SMCV relies on how samples are obtained in a study. When the groups are correlated, it is usually difficult to estimate the covariance among groups. In such a case, a good strategy is to obtain matched or paired samples (or subjects) and to conduct contrast analysis based on the matched samples. A simple example of matched contrast analysis is the analysis of paired difference of drug effects after and before taking a drug in the same patients. By contrast, another strategy is to not match or pair the samples and to conduct contrast analysis based on the unmatched or unpaired samples. A simple example of unmatched contrast analysis is the comparison of efficacy between a new drug taken by some patients and a standard drug taken by other patients. Methods of estimation for SMCV and c⁺-probability in matched contrast analysis may differ from those used in unmatched contrast analysis.

Unmatched samples

Consider an independent sample of size

,

from the

group . 's are independent. Let , and

When the

groups have unequal variance, the maximal likelihood estimate (MLE) and method-of-moment estimate (MM) of SMCV ( ) are, respectively^{[1] [2]} and

When the

groups have equal variance, under normality assumption, the uniformly minimal variance unbiased estimate (UMVUE) of SMCV ( ) is^{[1] [2]}

where

.

The confidence interval of SMCV can be made using the following non-central t-distribution:^{[1] [2]}

where

}.

Matched samples

In matched contrast analysis, assume that there are

independent samples from groups ( 's), where . Then the observed value of a contrast is .

Let

and be the sample mean and sample variance of the contrast variable , respectively. Under normality assumptions, the UMVUE estimate of SMCV is^[1] }

where

A confidence interval for SMCV can be made using the following non-central t-distribution:^[1]

} \sim \text t\left(n - 1, \sqrt\lambda\right).

See also

• Dual-flashlight plot

Notes and References

1. Book: Zhang XHD. 2011. Optimal High-Throughput Screening: Practical Experimental Design and Data Analysis for Genome-scale RNAi Research . Cambridge University Press. 978-0-521-73444-8.
2. Zhang XHD. A method for effectively comparing gene effects in multiple conditions in RNAi and expression-profiling research . Pharmacogenomics . 10 . 345–58 . 2009 . 20397965 . 10.2217/14622416.10.3.345 .
3. Zhang XHD. Assessing the size of gene or RNAi effects in multifactor high-throughput experiments . Pharmacogenomics . 11 . 199–213 . 2010 . 20136359. 10.2217/PGS.09.136 .
4. Book: Rosenthal R, Rosnow RL, Rubin DB . 2000 . Contrasts and Effect Sizes in Behavioral Research . Cambridge University Press . 0-521-65980-9.
5. Huberty CJ . A history of effect size indices . Educational and Psychological Measurement . 62 . 227–40 . 2002 . 10.1177/0013164402062002002 .
6. Kirk RE . Practical significance: A concept whose time has come . Educational and Psychological Measurement . 56 . 746–59 . 1996 . 10.1177/0013164496056005002 .
7. Cohen J . The statistical power of abnormal-social psychological research: A review . Journal of Abnormal and Social Psychology . 65 . 145–53 . 1962 . 13880271 . 10.1037/h0045186 .
8. Glass GV . Primary, secondary, and meta-analysis of research . Educational Researcher . 5 . 3–8 . 1976 . 10.3102/0013189X005010003 .
9. Steiger JH . Beyond the F test: Effect size confidence intervals and tests of close fit in the analysis of variance and contrast analysis . Psychological Methods . 9 . 164–82 . 2004 . 15137887. 10.1037/1082-989x.9.2.164 .