boot_null: Inference with specification curve analysis
In masurp/specr: Conducting and Visualizing Specification Curve Analyses
boot_null R Documentation
Inference with specification curve analysis
Description
It is possible to generate the distributions for any of these test statistics
under-the-null analytically (that is, with statistical formulas), because the
specifications are neither statistically independent nor part of a single model.
This function hence generates such distributions by relying on resampling under-the-null.
This involves modifying the observed data so that the null hypothesis is known to be true,
and then drawing random samples of the modified data. The resulting object of class
specr.boot can be summarized and plotted with generic functions.
Usage
boot_null(x, y, n_samples = 500, ...)
Arguments
x
A fitted specr.object, resulting from running specr().
y
A specr.setup object, resulting from running setup()
n_samples
Number of bootstrap samples to be drawn. Defaults to 500.
...
Further arguments that can be passed to future_map. This only becomes
important if parallelization is used. When a plan for parallelization is set, one
can also set .progress = TRUE to print a progress bar during the fitting process.
See details for more information on parallelization.
Details
A third step of specification curve analysis involves statistical inference,
answering the question: considering the full set of reasonable specifications jointly,
how inconsistent are the results with the null hypothesis of no effect?
\bold{Parallelization}
By default, the function fits the bootstrapped models across all specifications sequentially
(one after the other). If the data set is large, the models complex (e.g.,
large structural equation models, negative binomial models, or Bayesian models),
and the number of specifications is large, it can make sense to parallelize
these operations. One simply has to load the package furrr (which
in turn, builds on future) up front. Then parallelizing the fitting process
works as specified in the package description of furr/future by setting a
"plan" before running boot_null such as:
plan(multisession, workers = 4)
However, there are many more ways to specifically set up the plan, including
different strategy than multisession. For more information, see
vignette("parallelization") and the
reference page
for plan().
Value
a object of class specr.boot that represents a list with the original and bootstrapped results.
References
Simonsohn, U., Simmons, J.P. & Nelson, L.D. (2020). Specification curve analysis. Nature Human Behaviour, 4, 1208–1214. https://doi.org/10.1038/s41562-020-0912-z
Examples
# Setup up specifications
# Requires to keep full model
tidy_full <- function(x) {
fit <- broom::tidy(x, conf.int = TRUE)
fit$res <- list(x) # Store model object
return(fit)
}
specs <- setup(data = example_data,
y = c("y1", "y2"),
x = c("x1", "x2"),
model = "lm",
controls = c("c1", "c2"),
fun1 = tidy_full)
# Run analysis
results <- specr(specs)
# Run bootstrapping
boot_models <- boot_null(results, specs, n_samples = 2) # better 1,000!
# Summarize findings
summary(boot_models)
# Plot under-the-null curves on top of specification curve
plot(boot_models)
masurp/specr documentation built on March 17, 2024, 5:23 p.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.
| boot_null | R Documentation |
Inference with specification curve analysis
Description
It is possible to generate the distributions for any of these test statistics
under-the-null analytically (that is, with statistical formulas), because the
specifications are neither statistically independent nor part of a single model.
This function hence generates such distributions by relying on resampling under-the-null.
This involves modifying the observed data so that the null hypothesis is known to be true,
and then drawing random samples of the modified data. The resulting object of class
specr.boot can be summarized and plotted with generic functions.
Usage
boot_null(x, y, n_samples = 500, ...)
Arguments
x |
A fitted |
y |
A |
n_samples |
Number of bootstrap samples to be drawn. Defaults to 500. |
... |
Further arguments that can be passed to |
Details
A third step of specification curve analysis involves statistical inference, answering the question: considering the full set of reasonable specifications jointly, how inconsistent are the results with the null hypothesis of no effect?
\bold{Parallelization}
By default, the function fits the bootstrapped models across all specifications sequentially
(one after the other). If the data set is large, the models complex (e.g.,
large structural equation models, negative binomial models, or Bayesian models),
and the number of specifications is large, it can make sense to parallelize
these operations. One simply has to load the package furrr (which
in turn, builds on future) up front. Then parallelizing the fitting process
works as specified in the package description of furr/future by setting a
"plan" before running boot_null such as:
plan(multisession, workers = 4)
However, there are many more ways to specifically set up the plan, including
different strategy than multisession. For more information, see
vignette("parallelization") and the
reference page
for plan().
Value
a object of class specr.boot that represents a list with the original and bootstrapped results.
References
Simonsohn, U., Simmons, J.P. & Nelson, L.D. (2020). Specification curve analysis. Nature Human Behaviour, 4, 1208–1214. https://doi.org/10.1038/s41562-020-0912-z
Examples
# Setup up specifications
# Requires to keep full model
tidy_full <- function(x) {
fit <- broom::tidy(x, conf.int = TRUE)
fit$res <- list(x) # Store model object
return(fit)
}
specs <- setup(data = example_data,
y = c("y1", "y2"),
x = c("x1", "x2"),
model = "lm",
controls = c("c1", "c2"),
fun1 = tidy_full)
# Run analysis
results <- specr(specs)
# Run bootstrapping
boot_models <- boot_null(results, specs, n_samples = 2) # better 1,000!
# Summarize findings
summary(boot_models)
# Plot under-the-null curves on top of specification curve
plot(boot_models)
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.