Raw File
## ----message=FALSE, warning=FALSE, include=FALSE-------------------------
library(knitr)
options(knitr.kable.NA = '')
knitr::opts_chunk$set(comment=">")
options(digits=2)

set.seed(333)

## ----message=FALSE, warning=FALSE, echo=FALSE, fig.cap="Correlation between the frequentist p-value and the probability of direction (pd)", fig.align='center'----
library(dplyr)
library(tidyr)
library(ggplot2)
library(see)

read.csv("https://raw.github.com/easystats/easystats/master/publications/makowski_2019_bayesian/data/data.csv") %>% 
  mutate(effect_existence = ifelse(true_effect == 1, "Presence of true effect", "Absence of true effect"),
         p_direction = p_direction * 100) %>% 
  ggplot(aes(x=p_direction, y=p_value, color=effect_existence)) +
  geom_point2(alpha=0.1) +
  geom_segment(aes(x=95, y=Inf, xend=95, yend=0.1), color="black", linetype="longdash") +
  geom_segment(aes(x=-Inf, y=0.1, xend=95, yend=0.1), color="black", linetype="longdash") +
  geom_segment(aes(x=97.5, y=Inf, xend=97.5, yend=0.05), color="black", linetype="dashed") +
  geom_segment(aes(x=-Inf, y=0.05, xend=97.5, yend=0.05), color="black", linetype="dashed") +
  theme_modern() +
  scale_y_reverse(breaks = c(0.05, round(seq(0, 1, length.out = 11), digits=2))) +
  scale_x_continuous(breaks = c(95, 97.5, round(seq(50, 100, length.out = 6)))) +
  scale_color_manual(values=c("Presence of true effect"="green", "Absence of true effect"="red")) +
  theme(legend.title = element_blank()) +
  guides(colour = guide_legend(override.aes = list(alpha = 1))) +
  xlab("Probability of Direction (pd)") +
  ylab("Frequentist p-value")

## ----message=FALSE, warning=FALSE, fig.align='center'--------------------
library(bayestestR)
library(logspline)
library(KernSmooth)

# Compute the correlations
data <- data.frame()
for(the_mean in runif(25, 0, 4)){
  for(the_sd in runif(25, 0.5, 4)){
    x <- rnorm(100, the_mean, abs(the_sd))
    data <- rbind(data,
      data.frame("direct" = pd(x),
                 "kernel" = pd(x, method="kernel"),
                 "logspline" = pd(x, method="logspline"),
                 "KernSmooth" = pd(x, method="KernSmooth")
                 ))
  }
}
data <- as.data.frame(sapply(data, as.numeric))

# Visualize the correlations
library(ggplot2)
library(GGally)

GGally::ggpairs(data) +
  theme_classic()

## ----message=FALSE, warning=FALSE----------------------------------------
data <- data.frame()
for(i in 1:25){
  the_mean <- runif(1, 0, 4)
  the_sd <- abs(runif(1, 0.5, 4))
  parent_distribution <- rnorm(100000, the_mean, the_sd)
  true_pd <- pd(parent_distribution)
  
  for(j in 1:25){
    sample_size <- round(runif(1, 25, 5000))
    subsample <- sample(parent_distribution, sample_size)
    data <- rbind(data,
      data.frame("sample_size" = sample_size, 
                 "true" = true_pd,
                 "direct" = pd(subsample) - true_pd,
                 "kernel" = pd(subsample, method="kernel")- true_pd,
                 "logspline" = pd(subsample, method="logspline") - true_pd,
                 "KernSmooth" = pd(subsample, method="KernSmooth") - true_pd
                 ))
  }
}
data <- as.data.frame(sapply(data, as.numeric))

## ----message=FALSE, warning=FALSE, fig.align='center'--------------------
library(tidyr)
library(dplyr)

data %>% 
  tidyr::gather(Method, Distance, -sample_size, -true) %>% 
  ggplot(aes(x=sample_size, y = Distance, color = Method, fill= Method)) +
  geom_point(alpha=0.3, stroke=0, shape=16) +
  geom_smooth(alpha=0.2) +
  geom_hline(yintercept=0) +
  theme_classic() +
  xlab("\nDistribution Size")

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