Lab Overview

Time: ~30 minutes

Goal: Practice correlation analysis from start to finish using real public health data

Learning Objectives:

  • Understand when and why to use correlation analysis
  • Calculate and interpret Pearson correlation coefficients
  • Test hypotheses about correlation
  • Check correlation assumptions
  • Distinguish between correlation and causation
  • Use Spearman correlation for non-normal data

Structure:

  • Part A: Guided Examples (follow along with instructor)
  • Part B: Your Turn (independent practice)

Submission: Publish to RPubs and submit your .Rmd file + RPubs link to Brightspace by end of class

Background: Why Correlation Matters

What is Correlation?

Correlation measures the strength and direction of the LINEAR relationship between two continuous variables.

  • Range: -1 ≤ r ≤ 1
  • r = 1: Perfect positive relationship (as X ↑, Y ↑)
  • r = -1: Perfect negative relationship (as X ↑, Y ↓)
  • r = 0: No linear relationship
  • |r| > 0.7: Strong correlation
  • 0.3 < |r| < 0.7: Moderate correlation
  • |r| < 0.3: Weak correlation

When to Use Correlation

Use correlation when:

  • Both variables are continuous (or at least ordinal)
  • You want to measure strength/direction of linear relationship
  • You’re exploring data before regression
  • You want to describe associations (not causation)

Don’t use when:

  • One variable is categorical → use t-test or ANOVA
  • Relationship is clearly non-linear → consider transformation
  • You want to establish causation → use experimental design
  • You want to predict values → use regression

Important Warning

⚠️ CORRELATION ≠ CAUSATION

Just because two variables are correlated does NOT mean one causes the other!

Classic Example: Ice cream sales and drowning deaths are highly correlated. Does ice cream cause drowning? NO! Both increase in summer (confounding by temperature/season).

PART A: GUIDED EXAMPLES

Setup: Load Packages and Data

# Load NHANES data
data(NHANES)

# Select adult participants with complete data
nhanes_adult <- NHANES %>%
  filter(Age >= 18, Age <= 80) %>%
  select(Age, Weight, Height, BMI, BPSysAve, BPDiaAve, 
         Pulse, PhysActive, SleepHrsNight) %>%
  na.omit()

# Display sample
# Display sample size
data.frame(
  Metric = "Sample Size",
  Value = paste(nrow(nhanes_adult), "adults")
) %>%
  kable()
Metric Value
Sample Size 7133 adults 
head(nhanes_adult, 8) %>%
  kable(digits = 1, caption = "NHANES Adult Data Sample")
NHANES Adult Data Sample
Age Weight Height BMI BPSysAve BPDiaAve Pulse PhysActive SleepHrsNight
34 87.4 164.7 32.2 113 85 70 No 4
34 87.4 164.7 32.2 113 85 70 No 4
34 87.4 164.7 32.2 113 85 70 No 4
49 86.7 168.4 30.6 112 75 86 No 8
45 75.7 166.7 27.2 118 64 62 Yes 8
45 75.7 166.7 27.2 118 64 62 Yes 8
45 75.7 166.7 27.2 118 64 62 Yes 8
66 68.0 169.5 23.7 111 63 60 Yes 7

Dataset Description:

  • Age: Age in years
  • Weight: Weight in kg
  • BMI: Body Mass Index (kg/m²)
  • BPSysAve: Average systolic blood pressure (mmHg)
  • BPDiaAve: Average diastolic blood pressure (mmHg)
  • Pulse: 60 second pulse rate
  • SleepHrsNight: Hours of sleep per night

Example 1: Age and Blood Pressure

Research Question

Is there a correlation between age and systolic blood pressure among US adults?

Public Health Context: Understanding age-related changes in blood pressure helps identify at-risk populations and inform screening guidelines.

Step 1: Visualize the Relationship

Always start with a scatterplot!

# Create scatterplot
ggplot(nhanes_adult, aes(x = Age, y = BPSysAve)) +
  geom_point(alpha = 0.3, color = "steelblue") +
  geom_smooth(method = "lm", se = TRUE, color = "red") +
  labs(
    title = "Age vs Systolic Blood Pressure",
    subtitle = "NHANES Data, Adults 18-80 years",
    x = "Age (years)",
    y = "Systolic Blood Pressure (mmHg)"
  ) +
  theme_minimal()

What we observe:

  • Positive trend: older adults tend to have higher blood pressure
  • Points scattered around the line (not perfect relationship)
  • Relationship appears roughly linear
  • Some variability at all age levels

Step 2: Calculate Correlation

# Calculate Pearson correlation
cor_age_bp <- cor.test(nhanes_adult$Age, nhanes_adult$BPSysAve)

# Display results in clean table
tidy(cor_age_bp) %>%
  select(estimate, statistic, p.value, conf.low, conf.high) %>%
  kable(
    digits = 3,
    col.names = c("r", "t-statistic", "p-value", "95% CI Lower", "95% CI Upper"),
    caption = "Pearson Correlation: Age and Systolic BP"
  )
Pearson Correlation: Age and Systolic BP
r t-statistic p-value 95% CI Lower 95% CI Upper
0.415 38.54 0 0.396 0.434

Step 3: Interpret Results

Hypothesis Test:

  • H₀: ρ = 0 (no correlation between age and BP in population)
  • H₁: ρ ≠ 0 (correlation exists)
  • α = 0.05

Results:

  • r = 0.415: Moderate positive correlation
  • p < 0.001: Statistically significant (reject H₀)
  • 95% CI [0.396, 0.434]: Doesn’t contain zero (confirms significance)
# Calculate r-squared
r_squared <- cor_age_bp$estimate^2

data.frame(
  Measure = c("Correlation (r)", "Coefficient of Determination (r²)", 
              "Variance Explained"),
  Value = c(
    round(cor_age_bp$estimate, 3),
    round(r_squared, 3),
    paste0(round(r_squared * 100, 1), "%")
  )
) %>%
  kable(caption = "Summary of Correlation Strength")
Summary of Correlation Strength
Measure Value
Correlation (r) 0.415
Coefficient of Determination (r²) 0.172
Variance Explained 17.2%

Interpretation:

There is a statistically significant moderate positive correlation between age and systolic blood pressure. As age increases, systolic BP tends to increase. However, age explains only about 17.2% of the variation in BP, suggesting other factors also play important roles.

Public Health Implication: Age-appropriate BP screening is important, but individual risk assessment should consider multiple factors beyond age alone.

Step 4: Check Assumptions

Assumption 1: Linearity (already checked with scatterplot ✓)

Assumption 2: Bivariate Normality

# Q-Q plots for normality
par(mfrow = c(1, 2))

qqnorm(nhanes_adult$Age, main = "Q-Q Plot: Age")
qqline(nhanes_adult$Age, col = "red")

qqnorm(nhanes_adult$BPSysAve, main = "Q-Q Plot: Systolic BP")
qqline(nhanes_adult$BPSysAve, col = "red")

par(mfrow = c(1, 1))

Assessment: Both variables are approximately normally distributed (points follow the red line reasonably well). Some deviation in the tails, but with large sample size (n = 7133), the correlation test is robust to minor violations.

Assumption 3: No Extreme Outliers (scatterplot shows no extreme outliers ✓)

Example 2: BMI and Diastolic Blood Pressure

Research Question

Is BMI correlated with diastolic blood pressure?

Why this matters: Understanding the relationship between obesity and blood pressure helps inform weight management interventions.

Step 1: Visualize

ggplot(nhanes_adult, aes(x = BMI, y = BPDiaAve)) +
  geom_point(alpha = 0.3, color = "darkgreen") +
  geom_smooth(method = "lm", se = TRUE, color = "red", fill = "pink") +
  labs(
    title = "BMI vs Diastolic Blood Pressure",
    x = "Body Mass Index (kg/m²)",
    y = "Diastolic Blood Pressure (mmHg)"
  ) +
  theme_minimal()

Observation: Positive relationship visible, moderate scatter around the line.

Step 2: Calculate Correlation

# Pearson correlation
cor_bmi_bp <- cor.test(nhanes_adult$BMI, nhanes_adult$BPDiaAve)

# Display results
tidy(cor_bmi_bp) %>%
  select(estimate, statistic, p.value, conf.low, conf.high) %>%
  kable(
    digits = 3,
    col.names = c("r", "t-statistic", "p-value", "95% CI Lower", "95% CI Upper"),
    caption = "Pearson Correlation: BMI and Diastolic BP"
  )
Pearson Correlation: BMI and Diastolic BP
r t-statistic p-value 95% CI Lower 95% CI Upper
0.117 9.966 0 0.094 0.14 
# Calculate r-squared
r_squared_bmi <- cor_bmi_bp$estimate^2

data.frame(
  Measure = c("r²", "Variance Explained"),
  Value = c(
    round(r_squared_bmi, 4),
    paste0(round(r_squared_bmi * 100, 2), "%")
  )
) %>%
  kable(caption = "Effect Size")
Effect Size
Measure Value
cor 0.0137
Variance Explained 1.37%

Interpretation:

  • Moderate positive correlation (r = 0.117) between BMI and diastolic BP
  • Statistically significant (p < 0.001)
  • BMI explains only 1.4% of variation in diastolic BP

Key Insight: While BMI and blood pressure are related, BMI alone explains less than 10% of BP variation. Other factors (genetics, diet, physical activity, stress, age) play substantial roles.

Example 3: Correlation Matrix

Research Question

How are cardiovascular health indicators related to each other?

Step 1: Calculate Correlation Matrix

# Select cardiovascular variables
cardio_vars <- nhanes_adult %>%
  select(Age, BMI, BPSysAve, BPDiaAve, Pulse)

# Calculate correlation matrix
cor_matrix <- cor(cardio_vars, use = "complete.obs")

# Display as table
cor_matrix %>%
  kable(digits = 3, caption = "Cardiovascular Health Correlation Matrix")
Cardiovascular Health Correlation Matrix
Age BMI BPSysAve BPDiaAve Pulse
Age 1.000 0.065 0.415 -0.019 -0.153
BMI 0.065 1.000 0.135 0.117 0.112
BPSysAve 0.415 0.135 1.000 0.340 -0.022
BPDiaAve -0.019 0.117 0.340 1.000 0.106
Pulse -0.153 0.112 -0.022 0.106 1.000

Step 2: Visualize Correlation Matrix

# Create correlation plot
corrplot(cor_matrix, 
         method = "circle",
         type = "lower",
         tl.col = "black",
         tl.srt = 45,
         addCoef.col = "black",
         number.cex = 0.7,
         col = colorRampPalette(c("#3498db", "white", "#e74c3c"))(200),
         title = "Cardiovascular Health Correlations",
         mar = c(0,0,2,0))

Key Findings:

# Create summary table of notable correlations
data.frame(
  Relationship = c(
    "Systolic BP & Diastolic BP",
    "Age & Systolic BP",
    "Age & Diastolic BP",
    "BMI & Systolic BP",
    "BMI & Pulse"
  ),
  Correlation = c(
    round(cor_matrix["BPSysAve", "BPDiaAve"], 3),
    round(cor_matrix["Age", "BPSysAve"], 3),
    round(cor_matrix["Age", "BPDiaAve"], 3),
    round(cor_matrix["BMI", "BPSysAve"], 3),
    round(cor_matrix["BMI", "Pulse"], 3)
  ),
  Strength = c("Strong", "Moderate", "Weak-Moderate", "Moderate", "Very Weak")
) %>%
  kable(caption = "Notable Correlations Summary")
Notable Correlations Summary
Relationship Correlation Strength
Systolic BP & Diastolic BP 0.340 Strong
Age & Systolic BP 0.415 Moderate
Age & Diastolic BP -0.019 Weak-Moderate
BMI & Systolic BP 0.135 Moderate
BMI & Pulse 0.112 Very Weak

Interpretation: Systolic and diastolic BP show the strongest correlation (r = 0.34), which makes sense as they measure the same physiological process. Pulse rate shows relatively weak correlations, suggesting it’s influenced by different factors.

Example 4: Spearman vs Pearson

When to Use Spearman Correlation

Use Spearman’s rank correlation when:

  • Data are ordinal (ranked)
  • Relationship is monotonic but not linear
  • Data contain outliers
  • Normality assumption is violated

Example: Age vs Pulse Rate

# Visualize relationship
ggplot(nhanes_adult, aes(x = Age, y = Pulse)) +
  geom_point(alpha = 0.3, color = "purple") +
  geom_smooth(method = "lm", se = TRUE, color = "red") +
  labs(
    title = "Age vs Pulse Rate",
    x = "Age (years)",
    y = "Pulse Rate (bpm)"
  ) +
  theme_minimal()

# Calculate both correlations
pearson_r <- cor.test(nhanes_adult$Age, nhanes_adult$Pulse, method = "pearson")
spearman_r <- cor.test(nhanes_adult$Age, nhanes_adult$Pulse, method = "spearman")

# Compare in table
data.frame(
  Method = c("Pearson", "Spearman"),
  Correlation = c(
    round(pearson_r$estimate, 3),
    round(spearman_r$estimate, 3)
  ),
  p_value = c(
    format.pval(pearson_r$p.value),
    format.pval(spearman_r$p.value)
  ),
  Difference = c(
    "—",
    round(abs(pearson_r$estimate - spearman_r$estimate), 3)
  )
) %>%
  kable(caption = "Pearson vs Spearman Comparison")
Pearson vs Spearman Comparison
Method Correlation p_value Difference
cor Pearson -0.153 < 2.22e-16
rho Spearman -0.162 < 2.22e-16 0.008

Interpretation:

  • Results are very similar (difference < 0.01)
  • Both show very weak negative correlation
  • With large sample and only mild assumption violations, either method is appropriate
  • For this data, Pearson is fine (and has better statistical power)

Key Takeaways from Examples

  1. Always visualize first - scatterplots reveal patterns correlation coefficients miss
  2. Context matters - statistical significance ≠ practical importance
  3. Correlation ≠ Causation - always consider confounding
  4. r² tells you explained variance - even significant correlations may explain little
  5. Check assumptions - especially for small samples

PART B: YOUR TURN - Practice Problems

Now it’s your turn to practice! Use the same NHANES dataset and follow the examples above.

Total Points: 25 points

Problem 1: Weight and Height (10 points)

Research Question: Is there a correlation between weight and height among US adults?

Your tasks:

  1. Create a scatterplot with a fitted line (2 points)
  2. Calculate Pearson correlation using cor.test() and display with tidy() (3 points)
  3. Test for statistical significance and state your conclusion (2 points)
  4. Calculate r² and interpret in 2-3 sentences (3 points)
# YOUR CODE HERE

# Load NHANES data
data(NHANES)

# Select adult participants with complete data
nhanes_adult <- NHANES %>%
  filter(Age >= 18, Age <= 80) %>%
  select(Age, Weight, Height) %>%
  na.omit()

# Display sample
# Display sample size
data.frame(
  Metric = "Sample Size",
  Value = paste(nrow(nhanes_adult), "adults")
) %>%
  kable()
head(nhanes_adult, 8) %>%
  kable(digits = 1, caption = "NHANES Adult Data Sample")

# a. Scatterplot
# Create scatterplot
ggplot(nhanes_adult, aes(x = Height, y = Weight)) +
  geom_point(alpha = 0.3, color = "steelblue") +
  geom_smooth(method = "lm", se = TRUE, color = "red") +
  labs(
    title = "Height vs Weight",
    subtitle = "NHANES Data, Adults 18-80 years",
    x = "Height (cm)",
    y = "Weight (kg)"
  ) +
  theme_minimal()

# b. Correlation test with tidy() display
# Calculate Pearson correlation
cor_height_weight <- cor.test(nhanes_adult$Height, nhanes_adult$Weight)

# Display results in clean table
tidy(cor_height_weight) %>%
  select(estimate, statistic, p.value, conf.low, conf.high) %>%
  kable(
    digits = 3,
    col.names = c("r", "t-statistic", "p-value", "95% CI Lower", "95% CI Upper"),
    caption = "Pearson Correlation: Height and Weight"
  )

# c. Statistical significance
# Calculate r-squared
r_squared <- cor_height_weight$estimate^2

data.frame(
  Measure = c("Correlation (r)", "Coefficient of Determination (r²)", 
              "Variance Explained"),
  Value = c(
    round(cor_height_weight$estimate, 3),
    round(r_squared, 3),
    paste0(round(r_squared * 100, 1), "%")
  )
) %>%
  kable(caption = "Summary of Correlation Strength")

# d. r² and interpretation (write as comment)
# Interpretation:

# There is a statistically significant moderate positive correlation between height and weight (r = 0.45, p < .001). This shows that taller people tend to weigh more. The coefficient of determination (r² = 0.202) shows that approximately 20.2% of the variation in weight is explained by height. Height is a predictor of weight, but the majority of the variation is due to other factors such as diet and physical activity.

Problem 2: Correlation Matrix Analysis (10 points)

Research Question: What are the relationships among BMI, weight, and height?

Your tasks:

  1. Create a correlation matrix for: Weight, Height, BMI (3 points)
  2. Visualize the matrix using corrplot (3 points)
  3. Identify which pair has the strongest correlation (2 points)
  4. Explain why that correlation makes sense biologically/mathematically (2 points)
# YOUR CODE HERE

# Select adult participants with complete data
nhanes_adult <- NHANES %>%
  filter(Age >= 18, Age <= 80) %>%
  select(Weight, Height, BMI) %>%
  na.omit()

# a. Correlation matrix
# Replace cardiovascular variables
bmi_vars <- nhanes_adult %>%
  select(Weight, Height, BMI)

# Calculate correlation matrix
cor_matrix <- cor(bmi_vars, use = "complete.obs")

# Display as table
cor_matrix %>%
  kable(digits = 3, caption = "Correlation Matrix for Weight, Height and BMI")

# b. Visualize with corrplot
# Create correlation plot
corrplot(cor_matrix, 
         method = "circle",
         type = "upper",
         tl.col = "black",
         tl.srt = 45,
         addCoef.col = "black",
         number.cex = 0.7,
         col = colorRampPalette(c("#3498db", "white", "#e74c3c"))(200),
         title = "Correlations Within Weight, Height, and BMI",
         mar = c(0,0,2,0))

# c. Strongest correlation:
# Create summary table of notable correlations
data.frame(
  Relationship = c(
    "Weight & BMI",
    "Height & Weight",
    "Height & BMI"
),
  Correlation = c(
    round(cor_matrix["Weight", "BMI"], 3),
    round(cor_matrix["Height", "Weight"], 3),
    round(cor_matrix["Height", "BMI"], 3)
  ),
  Strength = c("Strong", "Moderate", "Weak")
) %>%
  kable(caption = "Correlation Summary for Weight, Height, and BMI")

# d. Explanation (write as comment)
# Weight and BMI show the strongest correlation since r =0.880.This makes sense mathematically because BMI is calculated by dividing the weight by the height squared.Since weight is directly used in the BMI formula, increases in weight lead to increases in BMI, showing a strong positive relationship. Biologically, greater body mass contributes to higher BMI values.

Problem 3: Sleep and Age (5 points)

Research Question: Is there a relationship between hours of sleep and age?

Your tasks:

  1. Create a scatterplot (1 point)
  2. Calculate Pearson correlation and display with tidy() (2 points)
  3. Interpret whether the relationship is statistically significant (2 points)
# YOUR CODE HERE

# Select adult participants with complete data
nhanes_adult <- NHANES %>%
  filter(Age >= 18, Age <= 80) %>%
  select(Age, SleepHrsNight) %>%
  na.omit()

# a. Scatterplot
# Create scatterplot
ggplot(nhanes_adult, aes(x = Age, y = SleepHrsNight)) +
  geom_point(alpha = 0.3, color = "steelblue") +
  geom_smooth(method = "lm", se = TRUE, color = "red") +
  labs(
    title = "Age vs Hours of Sleep",
    subtitle = "NHANES Data, Adults 18-80 years",
    x = "Age (years)",
    y = "Hours of Sleep A Night"
  ) +
  theme_minimal()

# b. Correlation with tidy()
# Calculate Pearson correlation
cor_age_sleep <- cor.test(nhanes_adult$Age, nhanes_adult$SleepHrsNight)

# Display results in clean table
tidy(cor_age_sleep) %>%
  select(estimate, statistic, p.value, conf.low, conf.high) %>%
  kable(
    digits = 3,
    col.names = c("r", "t-statistic", "p-value", "95% CI Lower", "95% CI Upper"),
    caption = "Pearson Correlation: Age and Hours of Sleep"
  )

# c. Interpretation (write as comment)
# # The correlation between age and hours of sleep is weak # (r = 0.022) and not statistically significant since the p-value is greater than 0.05. There is no statistically significant linear relationship between age and hours of sleep in the sample.

Bonus (Optional, 5 extra points)

Challenge: Investigate the relationship between two variables of your choice from the NHANES dataset. Include:

  • Scatterplot
  • Correlation test with clean display
  • Assumption checks
  • Thoughtful interpretation
# Select adult participants with complete data
nhanes_adult <- NHANES %>%
  filter(Age >= 18, Age <= 80) %>%
  select(Age, BMI) %>%
  na.omit()
# Dataset
age_bmi_data <- nhanes_adult %>%
  select(Age, BMI) %>%
  na.omit()

# Scatterplot
ggplot(age_bmi_data, aes(x = Age, y = BMI)) +
  geom_point(alpha = 0.3, color = "steelblue") +
  geom_smooth(method = "lm", se = TRUE, color = "red") +
  labs(
    title = "Age vs Body Mass Index (BMI)",
    subtitle = "NHANES Data, Adults 18-80 years",
    x = "Age (years)",
    y = "Body Mass Index (BMI)"
  ) +
  theme_minimal()

# Correlation test
cor_age_bmi <- cor.test(age_bmi_data$Age, age_bmi_data$BMI)

tidy(cor_age_bmi) %>%
  select(estimate, statistic, p.value, conf.low, conf.high) %>%
  kable(
    digits = 3,
    col.names = c("r", "t-statistic", "p-value",
                  "95% CI Lower", "95% CI Upper"),
    caption = "Pearson Correlation for Age and BMI"
  )
Pearson Correlation for Age and BMI
r t-statistic p-value 95% CI Lower 95% CI Upper
0.064 5.478 0 0.041 0.086 
# Q-Q plots for normality
par(mfrow = c(1, 2))

qqnorm(nhanes_adult$Age, main = "Q-Q Plot: Age")
qqline(nhanes_adult$Age, col = "red")

qqnorm(nhanes_adult$BMI, main = "Q-Q Plot: BMI")
qqline(nhanes_adult$BMI, col = "red")

par(mfrow = c(1, 1))

#Interpretation

#There is a statistically significant positive correlation between age and BMI since r = 0.064 and p < .001. However, the correlation itself is weak, showing that age explains very little variation in BMI. Assumption checks show the relationship is approximately linear. While the Q-Q plots display some deviation from perfect normality, Pearson correlation is robust with large sample sizes, proving that the test results are reliable.

Grading Rubric

Problem 1: Weight and Height (10 points)

    1. Scatterplot properly formatted with labels: 2 points
    1. Correct correlation with clean display: 3 points
    1. Significance test correctly interpreted: 2 points
    1. r² calculated and interpreted: 3 points

Problem 2: Correlation Matrix (10 points)

    1. Correct matrix calculated: 3 points
    1. Well-formatted correlation plot: 3 points
    1. Strongest correlation identified: 2 points
    1. Biological/mathematical explanation: 2 points

Problem 3: Sleep and Age (5 points)

    1. Scatterplot: 1 point
    1. Correlation calculated and displayed: 2 points
    1. Interpretation of significance: 2 points

Submission Instructions

  1. Save your work with your name: Correlation_Lab_YourName.Rmd

  2. Knit to HTML to create your report

  3. Publish to RPubs:

    • Click the Publish button (blue icon) in the HTML preview window
    • Choose RPubs from the options
    • Follow the prompts to publish (create account if needed)
    • Copy your RPubs URL

  4. Submit to Brightspace:

    • Upload your .Rmd file
    • Paste your RPubs link in the assignment comments or submission text box

  5. Due: End of class today

Grading: This lab is worth 15% of your in-class lab grade. The lowest 2 lab grades are dropped.

Additional Resources

R Functions Used Today

  • cor.test() - Calculate correlation and test significance
  • tidy() - Clean display of statistical test results
  • cor() - Calculate correlation matrix
  • corrplot() - Visualize correlation matrix
  • ggplot() + geom_point() - Scatterplots
  • geom_smooth(method="lm") - Add fitted regression line
  • qqnorm() / qqline() - Check normality

For More Help

  • Textbook: Chapter 6 - Correlation Analysis
  • Office Hours: See syllabus
  • TA Help: See syllabus
  • R Documentation: Type ?cor.test in console

Remember:

✓ Correlation measures LINEAR relationships only
✓ Always visualize your data first
✓ Correlation ≠ Causation
✓ Check your assumptions
✓ Consider confounding and alternative explanations

This lab activity was created for EPI 553: Principles of Statistical Inference II
University at Albany, College of Integrated Health Sciences
Spring 2026