Learn R Programming
phytools (version 0.6-44)

phylosig: Compute phylogenetic signal with two methods

Description

This function computes phylogenetic signal using two different methods. It can also conduct the hypothesis tests for significant phylogenetic signal, and estimate phylogenetic signal incorporating sampling error following Ives et al. (2007).

Usage

phylosig(tree, x, method="K", test=FALSE, nsim=1000, se=NULL, start=NULL,
   control=list())

Arguments

tree

a phylogenetic tree in "phylo" format.

x

vector containing values for a single continuously distributed trait.

method

method to compute signal: can be "K" or "lambda".

test

logical indicating whether or not to conduct a hypothesis test of "K" or "lambda".

nsim

for method="K", number of simulations in randomization test.

se

named vector containing the standard errors for each species.

start

vector of starting values for optimization of (respectively) sigma^2 and lambda. Only used in method="lambda" and se!=NULL.

control

list of control parameters for multidimensional optimization, implemented in optim. Only used in method="lambda" and se!=NULL.

Value

If (method="K"), a list with the following components:

K

value of the K-statistic.

sig2

rate of evolution, \(\sigma^2\), for estimation with sampling error.

logL

log-likelihood, for estimation with sampling error.

P

optionally, the P-value from the randomization test.

If (method="lambda"), a list with the following components:
lambda

fitted value of lambda.

sig2

rate of evolution, for estimation with sampling error.

logL

log-likelihood.

logL0

log-likelihood for lambda=0.0.

P

P-value of the likelihood ratio test.

convergence

value for convergence, for estimation with sampling error only. (See optim).

message

message from optim, for estimation with sampling error only.

Details

\(\lambda\) optimization is performed using optimize with the range of lambda set between 0 and the theoretical upper limit of lambda (determined by the relative height of the most recent internal node on the tree).

References

Blomberg, S. P., T. Garland Jr., A. R. Ives (2003) Testing for phylogenetic signal in comparative data: Behavioral traits are more labile. Evolution, 57, 717-745.

Ives, A. R., P. E. Midford, T. Garland Jr. (2007) Within-species variation and measurement error in phylogenetic comparative biology. Systematic Biology, 56, 252-270.

Pagel, M. (1999) Inferring the historical patterns of biological evolution. Nature, 401, 877-884.

Revell, L. J. (2012) phytools: An R package for phylogenetic comparative biology (and other things). Methods Ecol. Evol., 3, 217-223.

Examples

Run this code
# NOT RUN {
tree<-pbtree(n=100)
x<-fastBM(tree)
phylosig(tree,x,method="lambda",test=TRUE)
# }

Run the code above in your browser using DataLab