rTraitDisc: Discrete Character Simulation

Description

This function simulates the evolution of a discrete character along a phylogeny. If model is a character or a matrix, evolution is simulated with a Markovian model; the transition probabilities are calculated for each branch with \(P = e^{Qt}\) where \(Q\) is the rate matrix given by model and \(t\) is the branch length. The calculation is done recursively from the root. See Paradis (2006, p. 101) for a general introduction applied to evolution.

Usage

rTraitDisc(phy, model = "ER", k = if (is.matrix(model)) ncol(model) else 2,
           rate = 0.1, states = LETTERS[1:k], freq = rep(1/k, k),
           ancestor = FALSE, root.value = 1, ...)

Value

A factor with names taken from the tip labels of phy. If

ancestor = TRUE, the node labels are used if present, otherwise, ``Node1'', ``Node2'', etc.

Arguments

phy: an object of class "phylo".
model: a character, a square numeric matrix, or a function specifying the model (see details).
k: the number of states of the character.
rate: the rate of change used if model is a character; it is not recycled if model = "ARD" of model = "SYM".
states: the labels used for the states; by default ``A'', ``B'', ...
freq: a numeric vector giving the equilibrium relative frequencies of each state; by default the frequencies are equal.
ancestor: a logical value specifying whether to return the values at the nodes as well (by default, only the values at the tips are returned).
root.value: an integer giving the value at the root (by default, it's the first state). To have a random value, use root.value = sample(k).
...: further arguments passed to model if it is a function.

Author

Emmanuel Paradis

Details

There are three possibilities to specify model:

A matrix: it must be a numeric square matrix; the diagonal is always ignored. The arguments k and rate are ignored.
A character: these are the same short-cuts than in the function ace: "ER" is an equal-rates model, "ARD" is an all-rates-different model, and "SYM" is a symmetrical model. Note that the argument rate must be of the appropriate length, i.e., 1, \(k(k - 1)\), or \(k(k - 1)/2\) for the three models, respectively. The rate matrix \(Q\) is then filled column-wise.
A function: it must be of the form foo(x, l) where x is the trait of the ancestor and l is the branch length. It must return the value of the descendant as an integer.

References

Paradis, E. (2006) Analyses of Phylogenetics and Evolution with R. New York: Springer.

Examples

Run this code

data(bird.orders)
### the two followings are the same:
rTraitDisc(bird.orders)
rTraitDisc(bird.orders, model = matrix(c(0, 0.1, 0.1, 0), 2))

### two-state model with irreversibility:
rTraitDisc(bird.orders, model = matrix(c(0, 0, 0.1, 0), 2))

### simple two-state model:
tr <- rcoal(n <- 40, br = runif)
x <- rTraitDisc(tr, ancestor = TRUE)
plot(tr, show.tip.label = FALSE)
nodelabels(pch = 19, col = x[-(1:n)])
tiplabels(pch = 19, col = x[1:n])

### an imaginary model with stasis 0.5 time unit after a node, then
### random evolution:
foo <- function(x, l) {
    if (l < 0.5) return(x)
    sample(2, size = 1)
}
tr <- rcoal(20, br = runif)
x <- rTraitDisc(tr, foo, ancestor = TRUE)
plot(tr, show.tip.label = FALSE)
co <- c("blue", "yellow")
cot <- c("white", "black")
Y <- x[1:20]
A <- x[-(1:20)]
nodelabels(A, bg = co[A], col = cot[A])
tiplabels(Y, bg = co[Y], col = cot[Y])

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