Media priming theory suggests that exposure to different types of media can temporarily influence viewers’ thoughts and behaviors. In this study, we examine whether playing a violent video game, a non-violent video game, or completing an art project affects how much time 5th-grade students spend engaging in aggressive acts during recess.
Students who play the violent video game will spend more time engaging in aggressive acts during recess than the students who play the non-violent game or complete an art project. There will be a difference in aggressive acts among at least two of the activity categories.
The Independent Variable in this study is the type of activity completed before recess, with three different options: A violent video game, a non-violent video game, an art project.
The Dependent Variable in this study is the total time, in minutes, each student spent engaging in aggressive acts during recess.
A One-way ANOVA was conducted. This method was used to test for differences of aggressive behavior across three activity groups.
The results below show there was a significant difference among the groups.
| ANOVA Test Results | |||
| Statistic | df | df_resid | p_value |
|---|---|---|---|
| 420.86 | 2 | 87.94717 | < .001 |
| Tukey HSD Post-hoc Results | ||||
| Comparison | diff | lwr | upr | p adj |
|---|---|---|---|---|
| Nonviolent game-Art project | 0.90 | 0.38 | 1.42 | < .001 |
| Violent game-Art project | 5.79 | 5.27 | 6.30 | < .001 |
| Violent game-Nonviolent game | 4.89 | 4.37 | 5.40 | < .001 |
The results of this study support media priming theory: students who played a violent video game engaged in more aggressive acts during recess compared to those students who played the non-violent video game or worked on an art project.
# ============================================================
# Setup: Install and Load Required Packages
# ============================================================
if (!require("tidyverse")) install.packages("tidyverse")
if (!require("gt")) install.packages("gt")
if (!require("gtExtras")) install.packages("gtExtras")
if (!require("FSA")) install.packages("FSA")
if (!require("plotly")) install.packages("plotly")
library(tidyverse)
library(gt)
library(gtExtras)
library(FSA)
library(plotly)
options(scipen = 999) # suppress scientific notation
# ============================================================
# Step 1: Load Data
# ============================================================
mydata <- read.csv("Priming.csv") # <-- Edit YOURFILENAME.csv
# Specify DV and IV (edit column names here)
mydata$DV <- mydata$Value
mydata$IV <- mydata$Group
# ============================================================
# Step 2: Visualize Group Distributions (Interactive)
# ============================================================
# Compute group means
group_means <- mydata %>%
group_by(IV) %>%
summarise(mean_value = mean(DV), .groups = "drop")
# Interactive plot (boxplot + group means)
box_plot <- plot_ly() %>%
# Boxplot trace
add_trace(
data = mydata,
x = ~IV, y = ~DV,
type = "box",
boxpoints = "outliers", # only applies here
marker = list(color = "red", size = 4), # outlier style
line = list(color = "black"),
fillcolor = "royalblue",
name = ""
) %>%
# Group means (diamonds)
add_trace(
data = group_means,
x = ~IV, y = ~mean_value,
type = "scatter", mode = "markers",
marker = list(
symbol = "diamond", size = 9,
color = "black", line = list(color = "white", width = 1)
),
text = ~paste0("Mean = ", round(mean_value, 2)),
hoverinfo = "text",
name = "Group Mean"
) %>%
layout(
title = "Interactive Group Distributions with Means",
xaxis = list(title = "Independent Variable (IV)"),
yaxis = list(title = "Dependent Variable (DV)"),
showlegend = FALSE
)
# ============================================================
# Step 3: Descriptive Statistics by Group
# ============================================================
desc_stats <- mydata %>%
group_by(IV) %>%
summarise(
count = n(),
mean = mean(DV, na.rm = TRUE),
sd = sd(DV, na.rm = TRUE),
min = min(DV, na.rm = TRUE),
max = max(DV, na.rm = TRUE)
)
desc_table <- desc_stats %>%
mutate(across(where(is.numeric), ~round(.x, 2))) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "Descriptive Statistics by Group")
# ============================================================
# Step 4: Test Normality (Shapiro-Wilk)
# ============================================================
shapiro_results <- mydata %>%
group_by(IV) %>%
summarise(
W_statistic = shapiro.test(DV)$statistic,
p_value = shapiro.test(DV)$p.value
)
shapiro_table <- shapiro_results %>%
mutate(
W_statistic = round(W_statistic, 2),
p_value = ifelse(p_value < .001, "< .001", sprintf("%.3f", p_value))
) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "Shapiro-Wilk Normality Test by Group") %>%
tab_source_note(
source_note = "Note. If any p-value figures are 0.05 or less, if one or more group distributions appear non-normal, and any group sizes are less than 40, consider using the Kruskal-Wallis and Post-hoc Dunn’s Test results instead of the ANOVA and Tukey HSD Post-hoc results."
)
# ============================================================
# Step 5a: Non-Parametric Test (Kruskal-Wallis + Dunn)
# ============================================================
kruskal_res <- kruskal.test(DV ~ IV, data = mydata)
kruskal_table <- data.frame(
Statistic = round(kruskal_res$statistic, 2),
df = kruskal_res$parameter,
p_value = ifelse(kruskal_res$p.value < .001, "< .001",
sprintf("%.3f", kruskal_res$p.value))
) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "Kruskal-Wallis Test Results")
dunn_res <- dunnTest(DV ~ IV, data = mydata, method = "bonferroni")$res
dunn_table <- dunn_res %>%
mutate(
Z = round(Z, 2),
P.unadj = ifelse(P.unadj < .001, "< .001", sprintf("%.3f", P.unadj)),
P.adj = ifelse(P.adj < .001, "< .001", sprintf("%.3f", P.adj))
) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "Post-hoc Dunn’s Test Results")
# ============================================================
# Step 5b: Parametric Test (ANOVA + Tukey)
# ============================================================
anova_res <- oneway.test(DV ~ IV, data = mydata, var.equal = FALSE)
anova_table <- data.frame(
Statistic = round(anova_res$statistic, 2),
df = anova_res$parameter[1],
df_resid = anova_res$parameter[2],
p_value = ifelse(anova_res$p.value < .001, "< .001",
sprintf("%.3f", anova_res$p.value))
) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "ANOVA Test Results")
anova_model <- aov(DV ~ IV, data = mydata)
tukey_res <- TukeyHSD(anova_model)$IV %>% as.data.frame()
tukey_table <- tukey_res %>%
rownames_to_column("Comparison") %>%
mutate(
diff = round(diff, 2),
lwr = round(lwr, 2),
upr = round(upr, 2),
`p adj` = ifelse(`p adj` < .001, "< .001", sprintf("%.3f", `p adj`))
) %>%
gt() %>%
gt_theme_538() %>%
tab_header(title = "Tukey HSD Post-hoc Results")
# ============================================================
# Step 6: Display Key Results
# ============================================================
# Interactive box plot
box_plot
# Tables
desc_table
shapiro_table
anova_table
tukey_table
kruskal_table
dunn_table