babette Tutorial
Richèl J.C. Bilderbeek
2023-09-26
Introduction
This vignette is a tutorial how to use babette and its
most important bbt_run_from_model function.
First, load babette:
The main function of babette is
bbt_run_from_model. Here is part of its help:
Do a full run: create a 'BEAST2' configuration file (like BEAUti 2),
run 'BEAST2', parse results (like Tracer)
Usage
bbt_run_from_model(
fasta_filename,
inference_model,
beast2_options
)
Simplifying this to all arguments that do not have a default:
bbt_run_from_model(
fasta_filename
)
fasta_filename
fasta_filename is the argument to specify which FASTA
file to work on. babette is bundled with some FASTA files,
so obtaining a path to a FASTA file is easy:
fasta_filename <- get_babette_path("anthus_aco_sub.fas")
library(testthat)
expect_true(file.exists(fasta_filename))
With fasta_filename available, we have the minimal
requirements to call bbt_run_from_model like this:
out <- bbt_run_from_model(fasta_filename)
Note that this code is not ran, as it would take too long. The reason
this would take too long, is that the MCMC run that will be executed is
set to one million states by default. To specify the MCMC options and
shorten this run, the mcmc argument is used.
inference_model and mcmc
The inference run’s MCMC is part of the inference model. To get an
inference model with a short MCMC, create a test inference model like
this:
inference_model <- create_test_inference_model()
names(inference_model)
#> [1] "site_model" "clock_model" "tree_prior"
#> [4] "mrca_prior" "mcmc" "beauti_options"
#> [7] "tipdates_filename"
mcmc is the inference_model argument to
specify the MCMC run options:
print(inference_model$mcmc$chain_length)
#> [1] 3000
With these MCMC options, we can now call
bbt_run_from_model in way that it will finish fast:
if (is_beast2_installed()) {
beast2_options <- create_beast2_options()
out <- bbt_run_from_model(
fasta_filename = fasta_filename,
inference_model = inference_model,
beast2_options = beast2_options
)
bbt_delete_temp_files(
inference_model = inference_model,
beast2_options = beast2_options
)
}
#> [1] TRUE
The return value, out contains the results of the MCMC
run. For this tutorial, visualizing out is ignored, as the
‘Demo’ vignette discusses this. Instead, we will work through the other
bbt_run_from_model parameters.
site_model
site_model is the inference_model parameter
for a site model. As this tutorial works on a DNA alignment, such a site
model can also be called a nucleotide substitution model.
Picking a site model is easy: just type:
create_site_model_
This will trigger auto-complete to show all site models.
The simplest site model is the Jukes-Cantor DNA substitution model.
To use this model in babette, do:
inference_model <- create_test_inference_model(
site_model = create_jc69_site_model()
)
Using this site model:
if (is_beast2_installed()) {
beast2_options <- create_beast2_options()
out <- bbt_run_from_model(
fasta_filename = fasta_filename,
inference_model = inference_model,
beast2_options = beast2_options
)
bbt_delete_temp_files(
inference_model = inference_model,
beast2_options = beast2_options
)
}
#> [1] TRUE
clock_model
clock_models is the inference_model
parameter for a clock model.
Picking a clock model is easy: just type:
create_clock_model_
This will trigger auto-complete to show all clock models.
The simplest site model is the strict clock model. To use this model
in babette, do:
inference_model <- create_test_inference_model(
clock_model = create_strict_clock_model()
)
Using this clock model:
if (is_beast2_installed()) {
beast2_options <- create_beast2_options()
out <- bbt_run_from_model(
fasta_filename = fasta_filename,
inference_model = inference_model,
beast2_options = beast2_options
)
bbt_delete_temp_files(
inference_model = inference_model,
beast2_options = beast2_options
)
}
#> [1] TRUE
tree_prior
tree_prior is the inference_model parameter
to select a tree prior.
Picking a tree prior is easy: just type:
create_tree_prior_
This will trigger auto-complete to show all tree priors.
The simplest tree prior is the Yule (pure-birth) tree prior. To use
this model in babette, do:
inference_model <- create_test_inference_model(
tree_prior = create_yule_tree_prior()
)
Using this tree prior:
if (is_beast2_installed()) {
beast2_options <- create_beast2_options()
out <- bbt_run_from_model(
fasta_filename = fasta_filename,
inference_model = inference_model,
beast2_options = beast2_options
)
bbt_delete_temp_files(
inference_model = inference_model,
beast2_options = beast2_options
)
}
#> [1] TRUE
mrca_prior
mrca_priors is the inference_model
parameter to use a Most Recent Common Ancestor (hence, MRCA) prior. With
such a prior, it can be specified which taxa have a shared common
ancestor and when it existed.
Here is how to specify that the first two taxa in a FASTA file are
sister species:
mrca_prior <- create_mrca_prior(
alignment_id = get_alignment_id(fasta_filename = fasta_filename),
taxa_names = get_taxa_names(filename = fasta_filename)[1:2],
is_monophyletic = TRUE
)
To specify when the MRCA of all taxa was present, we’ll first create
a prior distribution of the crown age, after which we can use that
distribution.
To assume the crown age to follow a normal distribution, with a mean
of 15.0 (time units), with a standard deviation of 1.0, use
create_normal_distr:
mrca_distr <- create_normal_distr(
mean = 15.0,
sigma = 1.0
)
To use that distribution in our MRCA prior:
mrca_prior <- create_mrca_prior(
alignment_id = get_alignment_id(fasta_filename = fasta_filename),
taxa_names = get_taxa_names(filename = fasta_filename),
mrca_distr = mrca_distr
)
Using such an MRCA prior:
inference_model <- create_test_inference_model(
mrca_prior = mrca_prior
)
if (is_beast2_installed()) {
beast2_options <- create_beast2_options()
out <- bbt_run_from_model(
fasta_filename = fasta_filename,
inference_model = inference_model,
beast2_options = beast2_options
)
bbt_delete_temp_files(
inference_model = inference_model,
beast2_options = beast2_options
)
}
#> [1] TRUE