simSeq: Simulate sequences.
In KlausVigo/phangorn: Phylogenetic Reconstruction and Analysis
simSeq R Documentation
Simulate sequences.
Description
Simulate sequences from a given evolutionary tree.
Usage
simSeq(x, ...)
## S3 method for class 'phylo'
simSeq(x, l = 1000, Q = NULL, bf = NULL,
rootseq = NULL, type = "DNA", model = NULL, levels = NULL,
rate = 1, ancestral = FALSE, code = 1, ...)
## S3 method for class 'pml'
simSeq(x, ancestral = FALSE, ...)
Arguments
x
a phylogenetic tree tree, i.e. an object of class
phylo or and object of class pml.
...
Further arguments passed to or from other methods.
l
The length of the sequence to simulate.
Q
The rate matrix.
bf
Base frequencies.
rootseq
A vector of length l containing the root sequence.
If not provided, the root sequence is randomly generated.
type
Type of sequences ("DNA", "AA", "CODON" or "USER").
model
Amino acid model of evolution to employ, for example "WAG",
"JTT", "Dayhoff" or "LG". For a full list of supported models, type
phangorn:::.aamodels. Ignored if type is not equal to "AA".
levels
A character vector of the different character tokens.
Ignored unless type = "USER".
rate
A numerical value greater than zero giving the mutation rate
or scaler for edge lengths.
ancestral
Logical specifying whether to return ancestral sequences.
code
The ncbi genetic code number for translation (see details). By
default the standard genetic code is used.
Details
simSeq is a generic function to simulate sequence alignments
along a phylogeny. It is quite flexible and can generate DNA, RNA,
amino acids, codon, morphological or binary sequences.
simSeq can take as input a phylogenetic tree of class phylo,
or a pml object; it will return an object of class phyDat.
There is also a more low level
version, which lacks rate variation, but one can combine different
alignments with their own rates (see example). The rate parameter acts like
a scaler for the edge lengths.
For codon models type="CODON", two additional arguments dnds
for the dN/dS ratio and tstv for the transition transversion ratio
can be supplied.
Defaults:
If x is a tree of class phylo, then sequences will be generated
with the default Jukes-Cantor DNA model ("JC").
If bf is not specified, then all states will be treated as equally
probable.
If Q is not specified, then a uniform rate matrix will be employed.
Value
simSeq returns an object of class phyDat.
Author(s)
Klaus Schliep klaus.schliep@gmail.com
See Also
phyDat, pml, SOWH.test
Examples
## Not run:
data(Laurasiatherian)
tree <- nj(dist.ml(Laurasiatherian))
fit <- pml(tree, Laurasiatherian, k=4)
fit <- optim.pml(fit, optNni=TRUE, model="GTR", optGamma=TRUE)
data <- simSeq(fit)
## End(Not run)
tree <- rtree(5)
plot(tree)
nodelabels()
# Example for simple DNA alignment
data <- simSeq(tree, l = 10, type="DNA", bf=c(.1,.2,.3,.4), Q=1:6,
ancestral=TRUE)
as.character(data)
# Example to simulate discrete Gamma rate variation
rates <- discrete.gamma(1,4)
data1 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[1])
data2 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[2])
data3 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[3])
data4 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[4])
data <- c(data1,data2, data3, data4)
write.phyDat(data, file="temp.dat", format="sequential", nbcol = -1,
colsep = "")
unlink("temp.dat")
KlausVigo/phangorn documentation built on Nov. 5, 2024, 11 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
| simSeq | R Documentation |
Simulate sequences.
Description
Simulate sequences from a given evolutionary tree.
Usage
simSeq(x, ...)
## S3 method for class 'phylo'
simSeq(x, l = 1000, Q = NULL, bf = NULL,
rootseq = NULL, type = "DNA", model = NULL, levels = NULL,
rate = 1, ancestral = FALSE, code = 1, ...)
## S3 method for class 'pml'
simSeq(x, ancestral = FALSE, ...)
Arguments
x |
a phylogenetic tree |
... |
Further arguments passed to or from other methods. |
l |
The length of the sequence to simulate. |
Q |
The rate matrix. |
bf |
Base frequencies. |
rootseq |
A vector of length |
type |
Type of sequences ("DNA", "AA", "CODON" or "USER"). |
model |
Amino acid model of evolution to employ, for example "WAG",
"JTT", "Dayhoff" or "LG". For a full list of supported models, type
|
levels |
A character vector of the different character tokens. Ignored unless type = "USER". |
rate |
A numerical value greater than zero giving the mutation rate or scaler for edge lengths. |
ancestral |
Logical specifying whether to return ancestral sequences. |
code |
The ncbi genetic code number for translation (see details). By default the standard genetic code is used. |
Details
simSeq is a generic function to simulate sequence alignments
along a phylogeny. It is quite flexible and can generate DNA, RNA,
amino acids, codon, morphological or binary sequences.
simSeq can take as input a phylogenetic tree of class phylo,
or a pml object; it will return an object of class phyDat.
There is also a more low level
version, which lacks rate variation, but one can combine different
alignments with their own rates (see example). The rate parameter acts like
a scaler for the edge lengths.
For codon models type="CODON", two additional arguments dnds
for the dN/dS ratio and tstv for the transition transversion ratio
can be supplied.
Defaults:
If x is a tree of class phylo, then sequences will be generated
with the default Jukes-Cantor DNA model ("JC").
If bf is not specified, then all states will be treated as equally
probable.
If Q is not specified, then a uniform rate matrix will be employed.
Value
simSeq returns an object of class phyDat.
Author(s)
Klaus Schliep klaus.schliep@gmail.com
See Also
phyDat, pml, SOWH.test
Examples
## Not run:
data(Laurasiatherian)
tree <- nj(dist.ml(Laurasiatherian))
fit <- pml(tree, Laurasiatherian, k=4)
fit <- optim.pml(fit, optNni=TRUE, model="GTR", optGamma=TRUE)
data <- simSeq(fit)
## End(Not run)
tree <- rtree(5)
plot(tree)
nodelabels()
# Example for simple DNA alignment
data <- simSeq(tree, l = 10, type="DNA", bf=c(.1,.2,.3,.4), Q=1:6,
ancestral=TRUE)
as.character(data)
# Example to simulate discrete Gamma rate variation
rates <- discrete.gamma(1,4)
data1 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[1])
data2 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[2])
data3 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[3])
data4 <- simSeq(tree, l = 100, type="AA", model="WAG", rate=rates[4])
data <- c(data1,data2, data3, data4)
write.phyDat(data, file="temp.dat", format="sequential", nbcol = -1,
colsep = "")
unlink("temp.dat")
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.