Introduction to linear regression
The Human Freedom Index is a report that attempts to summarize the idea of “freedom” through a bunch of different variables for many countries around the globe. It serves as a rough objective measure for the relationships between the different types of freedom - whether it’s political, religious, economical or personal freedom - and other social and economic circumstances. The Human Freedom Index is an annually co-published report by the Cato Institute, the Fraser Institute, and the Liberales Institut at the Friedrich Naumann Foundation for Freedom.
In this lab, you’ll be analyzing data from Human Freedom Index reports from 2008-2016. Your aim will be to summarize a few of the relationships within the data both graphically and numerically in order to find which variables can help tell a story about freedom.
Getting Started
Load packages
In this lab, you will explore and visualize the data using the tidyverse suite of packages. The data can be found in the companion package for OpenIntro resources, openintro.
Let’s load the packages.
The data
The data we’re working with is in the openintro package and it’s
called hfi, short for Human Freedom Index.
- What are the dimensions of the dataset?
## [1] 1458 123- What type of plot would you use to display the relationship between
the personal freedom score,
pf_score, and one of the other numerical variables? Plot this relationship using the variablepf_expression_controlas the predictor. Does the relationship look linear? If you knew a country’spf_expression_control, or its score out of 10, with 0 being the most, of political pressures and controls on media content, would you be comfortable using a linear model to predict the personal freedom score?
ggplot(hfi, aes(x = pf_expression_control, y = pf_score)) +
geom_point() +
geom_smooth(method = "lm", se = FALSE, color = "blue") +
labs(
title = "Relationship between Personal Freedom Score and Expression Control",
x = "Expression Control Score (pf_expression_control)",
y = "Personal Freedom Score (pf_score)"
)
If the relationship looks linear, we can quantify the strength of the relationship with the correlation coefficient.
## # A tibble: 1 × 1
## `cor(pf_expression_control, pf_score, use = "complete.obs")`
## <dbl>
## 1 0.796Here, we set the use argument to “complete.obs” since
there are some observations of NA.
Sum of squared residuals
In this section, you will use an interactive function to investigate
what we mean by “sum of squared residuals”. You will need to run this
function in your console, not in your markdown document. Running the
function also requires that the hfi dataset is loaded in
your environment.
Think back to the way that we described the distribution of a single
variable. Recall that we discussed characteristics such as center,
spread, and shape. It’s also useful to be able to describe the
relationship of two numerical variables, such as
pf_expression_control and pf_score above.
- Looking at your plot from the previous exercise, describe the relationship between these two variables. Make sure to discuss the form, direction, and strength of the relationship as well as any unusual observations.
The form is linear, the direction is positive, and the strength is moderate to strong. There are some outliers that should be noted, as they may impact the fit of a linear model.
Just as you’ve used the mean and standard deviation to summarize a single variable, you can summarize the relationship between these two variables by finding the line that best follows their association. Use the following interactive function to select the line that you think does the best job of going through the cloud of points.
# This will only work interactively (i.e. will not show in the knitted document)
hfi <- hfi %>% filter(complete.cases(pf_expression_control, pf_score))
DATA606::plot_ss(x = hfi$pf_expression_control, y = hfi$pf_score)After running this command, you’ll be prompted to click two points on the plot to define a line. Once you’ve done that, the line you specified will be shown in black and the residuals in blue. Note that there are 30 residuals, one for each of the 30 observations. Recall that the residuals are the difference between the observed values and the values predicted by the line:
\[ e_i = y_i - \hat{y}_i \]
The most common way to do linear regression is to select the line
that minimizes the sum of squared residuals. To visualize the squared
residuals, you can rerun the plot command and add the argument
showSquares = TRUE.
Note that the output from the plot_ss function provides
you with the slope and intercept of your line as well as the sum of
squares.
- Using
plot_ss, choose a line that does a good job of minimizing the sum of squares. Run the function several times. What was the smallest sum of squares that you got? How does it compare to your neighbors?
# Make sure the data is properly filtered for complete cases
hfi_clean <- hfi %>% filter(complete.cases(pf_expression_control, pf_score))
# Use plot_ss() to visually analyze the line of best fit
DATA606::plot_ss(x = hfi_clean$pf_expression_control, y = hfi_clean$pf_score)
## Click two points to make a line.
## Call:
## lm(formula = y ~ x, data = pts)
##
## Coefficients:
## (Intercept) x
## 4.6171 0.4914
##
## Sum of Squares: 952.153The linear model
It is rather cumbersome to try to get the correct least squares line,
i.e. the line that minimizes the sum of squared residuals, through trial
and error. Instead, you can use the lm function in R to fit
the linear model (a.k.a. regression line).
The first argument in the function lm is a formula that
takes the form y ~ x. Here it can be read that we want to
make a linear model of pf_score as a function of
pf_expression_control. The second argument specifies that R
should look in the hfi data frame to find the two
variables.
The output of lm is an object that contains all of the
information we need about the linear model that was just fit. We can
access this information using the summary function.
##
## Call:
## lm(formula = pf_score ~ pf_expression_control, data = hfi)
##
## Residuals:
## Min 1Q Median 3Q Max
## -3.8467 -0.5704 0.1452 0.6066 3.2060
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 4.61707 0.05745 80.36 <2e-16 ***
## pf_expression_control 0.49143 0.01006 48.85 <2e-16 ***
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 0.8318 on 1376 degrees of freedom
## (80 observations deleted due to missingness)
## Multiple R-squared: 0.6342, Adjusted R-squared: 0.634
## F-statistic: 2386 on 1 and 1376 DF, p-value: < 2.2e-16Let’s consider this output piece by piece. First, the formula used to
describe the model is shown at the top. After the formula you find the
five-number summary of the residuals. The “Coefficients” table shown
next is key; its first column displays the linear model’s y-intercept
and the coefficient of pf_expression_control. With this
table, we can write down the least squares regression line for the
linear model:
\[ \hat{y} = 4.61707 + 0.49143 \times pf\_expression\_control \]
One last piece of information we will discuss from the summary output is the Multiple R-squared, or more simply, \(R^2\). The \(R^2\) value represents the proportion of variability in the response variable that is explained by the explanatory variable. For this model, 63.42% of the variability in runs is explained by at-bats.
- Fit a new model that uses
pf_expression_controlto predicthf_score, or the total human freedom score. Using the estimates from the R output, write the equation of the regression line. What does the slope tell us in the context of the relationship between human freedom and the amount of political pressure on media content?
# Load the data
data('hfi', package='openintro')
# Remove missing values for the required columns
hfi_clean <- hfi %>% filter(complete.cases(pf_expression_control, hf_score))
# Fit the linear model
model_hf <- lm(hf_score ~ pf_expression_control, data = hfi_clean)
summary(model_hf)##
## Call:
## lm(formula = hf_score ~ pf_expression_control, data = hfi_clean)
##
## Residuals:
## Min 1Q Median 3Q Max
## -2.6198 -0.4908 0.1031 0.4703 2.2933
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 5.153687 0.046070 111.87 <2e-16 ***
## pf_expression_control 0.349862 0.008067 43.37 <2e-16 ***
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 0.667 on 1376 degrees of freedom
## Multiple R-squared: 0.5775, Adjusted R-squared: 0.5772
## F-statistic: 1881 on 1 and 1376 DF, p-value: < 2.2e-16hf_score =5.153687+0.349862×pf_expression_control For each additional amount of political pressure on media content score, we would expect the human freedom score to increase by 0.3499
Intercept: The human freedom score with no amount of political pressure on media is 5.1537.
Prediction and prediction errors
Let’s create a scatterplot with the least squares line for
m1 laid on top.
ggplot(data = hfi, aes(x = pf_expression_control, y = pf_score)) +
geom_point() +
stat_smooth(method = "lm", se = FALSE)
Here, we are literally adding a layer on top of our plot.
geom_smooth creates the line by fitting a linear model. It
can also show us the standard error se associated with our
line, but we’ll suppress that for now.
This line can be used to predict \(y\) at any value of \(x\). When predictions are made for values of \(x\) that are beyond the range of the observed data, it is referred to as extrapolation and is not usually recommended. However, predictions made within the range of the data are more reliable. They’re also used to compute the residuals.
- If someone saw the least squares regression line and not the actual
data, how would they predict a country’s personal freedom school for one
with a 6.7 rating for
pf_expression_control? Is this an overestimate or an underestimate, and by how much? In other words, what is the residual for this prediction?
## [1] 7.909651Model diagnostics
To assess whether the linear model is reliable, we need to check for (1) linearity, (2) nearly normal residuals, and (3) constant variability.
Linearity: You already checked if the relationship
between pf_score and `pf_expression_control’ is linear
using a scatterplot. We should also verify this condition with a plot of
the residuals vs. fitted (predicted) values.
ggplot(data = m1, aes(x = .fitted, y = .resid)) +
geom_point() +
geom_hline(yintercept = 0, linetype = "dashed") +
xlab("Fitted values") +
ylab("Residuals")
Notice here that m1 can also serve as a data set because
stored within it are the fitted values (\(\hat{y}\)) and the residuals. Also note
that we’re getting fancy with the code here. After creating the
scatterplot on the first layer (first line of code), we overlay a
horizontal dashed line at \(y = 0\) (to
help us check whether residuals are distributed around 0), and we also
reanme the axis labels to be more informative.
- Is there any apparent pattern in the residuals plot? What does this indicate about the linearity of the relationship between the two variables?
# Plotting residuals vs. fitted values
plot(model_hf$fitted.values, model_hf$residuals,
xlab = "Fitted Values",
ylab = "Residuals",
main = "Residuals vs Fitted Values")
abline(h = 0, col = "red")
Nearly normal residuals: To check this condition, we can look at a histogram
or a normal probability plot of the residuals.
Note that the syntax for making a normal probability plot is a bit
different than what you’re used to seeing: we set sample
equal to the residuals instead of x, and we set a
statistical method qq, which stands for
“quantile-quantile”, another name commonly used for normal probability
plots.
- Based on the histogram and the normal probability plot, does the nearly normal residuals condition appear to be met?
Both the histogram and the normal probability plot show that the distribution of these data are nearly normal. Thus, the nearly normal residuals condition appear to be met.
Constant variability:
- Based on the residuals vs. fitted plot, does the constant variability condition appear to be met?
The residuals vs. fitted plot shows that the points are scattered around 0 with a consistent level of variability. Therefore, the condition of constant variability appears to be satisfied
More Practice
- Choose another freedom variable and a variable you think would strongly correlate with it.. Produce a scatterplot of the two variables and fit a linear model. At a glance, does there seem to be a linear relationship?
## [1] "year" "ISO_code"
## [3] "countries" "region"
## [5] "pf_rol_procedural" "pf_rol_civil"
## [7] "pf_rol_criminal" "pf_rol"
## [9] "pf_ss_homicide" "pf_ss_disappearances_disap"
## [11] "pf_ss_disappearances_violent" "pf_ss_disappearances_organized"
## [13] "pf_ss_disappearances_fatalities" "pf_ss_disappearances_injuries"
## [15] "pf_ss_disappearances" "pf_ss_women_fgm"
## [17] "pf_ss_women_missing" "pf_ss_women_inheritance_widows"
## [19] "pf_ss_women_inheritance_daughters" "pf_ss_women_inheritance"
## [21] "pf_ss_women" "pf_ss"
## [23] "pf_movement_domestic" "pf_movement_foreign"
## [25] "pf_movement_women" "pf_movement"
## [27] "pf_religion_estop_establish" "pf_religion_estop_operate"
## [29] "pf_religion_estop" "pf_religion_harassment"
## [31] "pf_religion_restrictions" "pf_religion"
## [33] "pf_association_association" "pf_association_assembly"
## [35] "pf_association_political_establish" "pf_association_political_operate"
## [37] "pf_association_political" "pf_association_prof_establish"
## [39] "pf_association_prof_operate" "pf_association_prof"
## [41] "pf_association_sport_establish" "pf_association_sport_operate"
## [43] "pf_association_sport" "pf_association"
## [45] "pf_expression_killed" "pf_expression_jailed"
## [47] "pf_expression_influence" "pf_expression_control"
## [49] "pf_expression_cable" "pf_expression_newspapers"
## [51] "pf_expression_internet" "pf_expression"
## [53] "pf_identity_legal" "pf_identity_parental_marriage"
## [55] "pf_identity_parental_divorce" "pf_identity_parental"
## [57] "pf_identity_sex_male" "pf_identity_sex_female"
## [59] "pf_identity_sex" "pf_identity_divorce"
## [61] "pf_identity" "pf_score"
## [63] "pf_rank" "ef_government_consumption"
## [65] "ef_government_transfers" "ef_government_enterprises"
## [67] "ef_government_tax_income" "ef_government_tax_payroll"
## [69] "ef_government_tax" "ef_government"
## [71] "ef_legal_judicial" "ef_legal_courts"
## [73] "ef_legal_protection" "ef_legal_military"
## [75] "ef_legal_integrity" "ef_legal_enforcement"
## [77] "ef_legal_restrictions" "ef_legal_police"
## [79] "ef_legal_crime" "ef_legal_gender"
## [81] "ef_legal" "ef_money_growth"
## [83] "ef_money_sd" "ef_money_inflation"
## [85] "ef_money_currency" "ef_money"
## [87] "ef_trade_tariffs_revenue" "ef_trade_tariffs_mean"
## [89] "ef_trade_tariffs_sd" "ef_trade_tariffs"
## [91] "ef_trade_regulatory_nontariff" "ef_trade_regulatory_compliance"
## [93] "ef_trade_regulatory" "ef_trade_black"
## [95] "ef_trade_movement_foreign" "ef_trade_movement_capital"
## [97] "ef_trade_movement_visit" "ef_trade_movement"
## [99] "ef_trade" "ef_regulation_credit_ownership"
## [101] "ef_regulation_credit_private" "ef_regulation_credit_interest"
## [103] "ef_regulation_credit" "ef_regulation_labor_minwage"
## [105] "ef_regulation_labor_firing" "ef_regulation_labor_bargain"
## [107] "ef_regulation_labor_hours" "ef_regulation_labor_dismissal"
## [109] "ef_regulation_labor_conscription" "ef_regulation_labor"
## [111] "ef_regulation_business_adm" "ef_regulation_business_bureaucracy"
## [113] "ef_regulation_business_start" "ef_regulation_business_bribes"
## [115] "ef_regulation_business_licensing" "ef_regulation_business_compliance"
## [117] "ef_regulation_business" "ef_regulation"
## [119] "ef_score" "ef_rank"
## [121] "hf_score" "hf_rank"
## [123] "hf_quartile"# Filter the data to remove missing values in the chosen columns
hfi_filtered <- hfi_clean %>% filter(complete.cases(pf_religion, hf_score))
# Scatterplot of pf_religion and hf_score
ggplot(hfi_filtered, aes(x = pf_religion, y = hf_score)) +
geom_point() +
geom_smooth(method = "lm", se = FALSE, color = "blue") +
labs(
title = "Scatterplot of Religion Freedom vs. Human Freedom Score",
x = "Religion Freedom Score (pf_religion)",
y = "Total Human Freedom Score (hf_score)"
)
# Fit the linear model
model_religion <- lm(hf_score ~ pf_religion, data = hfi_filtered)
summary(model_religion)##
## Call:
## lm(formula = hf_score ~ pf_religion, data = hfi_filtered)
##
## Residuals:
## Min 1Q Median 3Q Max
## -3.10229 -0.58501 -0.04865 0.77466 2.00693
##
## Coefficients:
## Estimate Std. Error t value Pr(>|t|)
## (Intercept) 4.7081 0.1502 31.34 <2e-16 ***
## pf_religion 0.2917 0.0188 15.51 <2e-16 ***
## ---
## Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
##
## Residual standard error: 0.9377 on 1366 degrees of freedom
## Multiple R-squared: 0.1497, Adjusted R-squared: 0.1491
## F-statistic: 240.6 on 1 and 1366 DF, p-value: < 2.2e-16- How does this relationship compare to the relationship between
pf_expression_controlandpf_score? Use the \(R^2\) values from the two model summaries to compare. Does your independent variable seem to predict your dependent one better? Why or why not?
Based on the R-squared values from the two models, pf_expression_control appears to be a better predictor of pf_score compared to pf_religion for hf_score. This implies that freedom from political pressure on media is more closely related to personal freedom than religion freedom is related to overall human freedom, possibly indicating that media freedom plays a more significant role in influencing the perception of personal freedom.
- What’s one freedom relationship you were most surprised about and why? Display the model diagnostics for the regression model analyzing this relationship.
# Fit the model again if necessary
model_religion <- lm(hf_score ~ pf_religion, data = hfi_filtered)
# Display diagnostic plots
par(mfrow = c(2, 2)) # Arrange for 4 plots
plot(model_religion)
Residuals vs Fitted Plot:
If the points are randomly scattered around zero, it indicates that the linear model fits well. However, if there is a clear pattern, it suggests non-linearity.
Normal Q-Q Plot:
If the residuals roughly follow the 45-degree line, they are normally distributed. Deviations from this indicate potential non-normality.
Scale-Location Plot:
A consistent spread of residuals indicates homoscedasticity. If the spread changes, it suggests heteroscedasticity, indicating issues with constant variance.
Residuals vs Leverage Plot:
Points far from the majority (high leverage or large residuals) can be influential. Cook’s distance helps identify these influential points. * * *