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geomorph (version 3.1.2)

compare.pls: Comparisons of Effect Sizes from Partial Least Squares

Description

Function performs an analysis to compare the effect sizes of two or more PLS effects

Usage

compare.pls(...)

Arguments

...

saved analyses of class pls

Value

An object of class compare.pls, returns a list of the following

sample.z

A vector of effect sizes for each sample.

sample.r.sd

A vector of standard deviations for each sampling distribution.

pairwise.z

A matrix of pairwise, two-sample z scores between all pairs of effect sizes.

pairwise.p

A matrix of corresponding P-values.

Details

The function statistically compares the effect sizes of two or more PLS analyses. Typically, this function might be used to compare levels of integration between two or more samples, each measuring morphological integration between different modules. In such cases, the PLS correlation coefficient, r, is not a good measure of integration effect, as its expected value is dependent on both the number of specimens and number of variables (Adams and Collyer 2016). This analysis calculates effect sizes as standard deviates, z, and performs two-sample z-tests, using the pooled standard error from the sampling distributions of the PLS analyses.

To use this function, simply perform two.b.pls, integration.test, or phylo.integration on as many samples as desired. Any number of objects of class pls can be input.

Similar versions of this function will be designed for alternative test statistics, in the future.

Notes for geomorph 3.0.4 and subsequent versions

Compared to previous versions of geomorph, users might notice differences in effect sizes. Previous versions used z-scores calculated with expected values of statistics from null hypotheses (sensu Collyer et al. 2015); however Adams and Collyer (2016) showed that expected values for some statistics can vary with sample size and variable number, and recommended finding the expected value, empirically, as the mean from the set of random outcomes. Geomorph 3.0.4 and subsequent versions now center z-scores on their empirically estimated expected values and where appropriate, log-transform values to assure statistics are normally distributed. This can result in negative effect sizes, when statistics are smaller than expected compared to the average random outcome. For ANOVA-based functions, the option to choose among different statistics to measure effect size is now a function argument.

References

Collyer, M.L., D.J. Sekora, and D.C. Adams. 2015. A method for analysis of phenotypic change for phenotypes described by high-dimensional data. Heredity. 115:357-365.

Adams, D.C. and M.L. Collyer. 2016. On the comparison of the strength of morphological integration across morphometric datasets. Evolution. 70:2623-2631.

Examples

Run this code
# NOT RUN {
# Example of comparative morphological integration between pupfish head and body shapes

 data(pupfish) # GPA previously performed
  
 group <- factor(paste(pupfish$Pop, pupfish$Sex, sep = "."))
 levels(group)
  
 tail.LM <- c(1:3, 5:9, 18:38)
 head.LM <- (1:56)[-tail.LM]

 tail.coords <- pupfish$coords[tail.LM,,]
 head.coords <- pupfish$coords[head.LM,,]
 
 # Subset 3D array by group, returning a list of 3D arrays
 tail.coords.gp <- coords.subset(tail.coords, group)
 head.coords.gp <- coords.subset(head.coords, group)

 integ.tests <- Map(function(x,y) integration.test(x, y, iter=499), head.coords.gp, tail.coords.gp)
# the map function performs the integration test on each 3D array in the lists provided

 integ.tests$Marsh.F
 integ.tests$Marsh.M
 integ.tests$Sinkhole.F
 integ.tests$Sinkhole.M

 group.Z <- compare.pls(integ.tests)
 summary(group.Z)

 # Sexual dimorphism in morphological integration in one population
 # but not the other

 # can also list different PLS analyses, separately

 compare.pls(MF = integ.tests$Marsh.F, MM = integ.tests$Marsh.M)

# }

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