https://github.com/cran/bayestestR
Raw File
Tip revision: d2eac42f58e4e0f0d07298e8c2e719ef6a30672d authored by Dominique Makowski on 19 June 2020, 08:00 UTC
version 0.7.0
Tip revision: d2eac42
estimate_density.Rd
% Generated by roxygen2: do not edit by hand
% Please edit documentation in R/estimate_density.R
\name{estimate_density}
\alias{estimate_density}
\alias{estimate_density.data.frame}
\title{Density Estimation}
\usage{
estimate_density(
  x,
  method = "kernel",
  precision = 2^10,
  extend = FALSE,
  extend_scale = 0.1,
  bw = "SJ",
  ...
)

\method{estimate_density}{data.frame}(
  x,
  method = "kernel",
  precision = 2^10,
  extend = FALSE,
  extend_scale = 0.1,
  bw = "SJ",
  group_by = NULL,
  ...
)
}
\arguments{
\item{x}{Vector representing a posterior distribution, or a data frame of such
vectors. Can also be a Bayesian model (\code{stanreg}, \code{brmsfit},
\code{MCMCglmm}, \code{mcmc} or \code{bcplm}) or a \code{BayesFactor} model.}

\item{method}{Density estimation method. Can be \code{"kernel"} (default), \code{"logspline"} or \code{"KernSmooth"}.}

\item{precision}{Number of points of density data. See the \code{n} parameter in \code{density}.}

\item{extend}{Extend the range of the x axis by a factor of \code{extend_scale}.}

\item{extend_scale}{Ratio of range by which to extend the x axis. A value of \code{0.1} means that the x axis will be extended by \code{1/10} of the range of the data.}

\item{bw}{See the eponymous argument in \code{density}. Here, the default has been changed for \code{"SJ"}, which is recommended.}

\item{...}{Currently not used.}

\item{group_by}{Optional character vector. If not \code{NULL} and \code{x} is a data frame, density estimation is performed for each group (subset) indicated by \code{group_by}.}
}
\description{
This function is a wrapper over different methods of density estimation. By default, it uses the base R \code{density} with by default uses a different smoothing bandwidth (\code{"SJ"}) from the legacy default implemented the base R \code{density} function (\code{"nrd0"}). However, Deng \& Wickham suggest that \code{method = "KernSmooth"} is the fastest and the most accurate.
}
\note{
There is also a \href{https://easystats.github.io/see/articles/bayestestR.html}{\code{plot()}-method} implemented in the \href{https://easystats.github.io/see/}{\pkg{see}-package}.
}
\examples{
library(bayestestR)

set.seed(1)
x <- rnorm(250, 1)

# Methods
density_kernel <- estimate_density(x, method = "kernel")
density_logspline <- estimate_density(x, method = "logspline")
density_KernSmooth <- estimate_density(x, method = "KernSmooth")
density_mixture <- estimate_density(x, method = "mixture")

hist(x, prob = TRUE)
lines(density_kernel$x, density_kernel$y, col = "black", lwd = 2)
lines(density_logspline$x, density_logspline$y, col = "red", lwd = 2)
lines(density_KernSmooth$x, density_KernSmooth$y, col = "blue", lwd = 2)
lines(density_mixture$x, density_mixture$y, col = "green", lwd = 2)

# Extension
density_extended <- estimate_density(x, extend = TRUE)
density_default <- estimate_density(x, extend = FALSE)

hist(x, prob = TRUE)
lines(density_extended$x, density_extended$y, col = "red", lwd = 3)
lines(density_default$x, density_default$y, col = "black", lwd = 3)

df <- data.frame(replicate(4, rnorm(100)))
head(estimate_density(df))
\dontrun{
# rstanarm models
# -----------------------------------------------
library(rstanarm)
model <- stan_glm(mpg ~ wt + gear, data = mtcars, chains = 2, iter = 200, refresh = 0)
head(estimate_density(model))

library(emmeans)
head(estimate_density(emtrends(model, ~1, "wt")))

# brms models
# -----------------------------------------------
library(brms)
model <- brms::brm(mpg ~ wt + cyl, data = mtcars)
estimate_density(model)
}

}
\references{
Deng, H., & Wickham, H. (2011). Density estimation in R. Electronic publication.
}
back to top