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Chapter 7

Chapter 7. Scatterplots, Association, and Correlation. Examining Relationships. Relationship between two variables Examples: Height and Weight Alcohol and Body Temperature SAT Verbal Score and SAT Math Score High School GPA and College GPA. Two Types of Variables.

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Chapter 7

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  1. Chapter 7 Scatterplots, Association, and Correlation

  2. Examining Relationships • Relationship between two variables • Examples: • Height and Weight • Alcohol and Body Temperature • SAT Verbal Score and SAT Math Score • High School GPA and College GPA

  3. Two Types of Variables • Response Variable (Dependent) • Measures an outcome of the study • Explanatory Variable (Independent) • Used to explain the response variable. • Example: Alcohol and Body Temp • Explanatory Variable: Alcohol • Response Variable: Body Temperature

  4. Two Types of Variables • Does not mean that explanatory variable causes response variable • It helps explain the response • Sometimes there are no true response or explanatory variables • Ex. Height and Weight • SAT Verbal and SAT Math Scores

  5. Graphing Two Variables • Plot of explanatory variable vs. response variable • Explanatory variable goes on horizontal axis (x) • Response variable goes on vertical axis (y) • If response and explanatory variables do not exist, you can plot the variables on either axis. • This plot is called a scatterplot • This plot can only be used if explanatory and response variables are both quantitative.

  6. Scatterplots • Scatterplots show patterns, trends, and relationships. • When interpreting a scatterplot (i.e., describing the relationship between two variables) always look at the following: • Overall Pattern • Form • Direction • Strength • Deviations from the Pattern • Outliers

  7. Interpreting Scatterplots • Form • Is the plot linear or is it curved? • Strength • Does the plot follow the form very closely or is there a lot of scatter (variation)?

  8. Interpreting Scatterplots • Direction • Is the plot increasing or is it decreasing? • Positively Associated • Above (below) average in one variable tends to be associated with above (below) average in another variable. • Negative Associated • Above (below) average in one variable tends to be associated with below (above) average in another variable.

  9. Example – Scatterplot • The following survey was conducted in the U.S. and in 10 countries of Western Europe to determine the percentage of teenagers who had used marijuana and other drugs.

  10. Percent who have used Country Marijuana Other Drugs Czech Republic 22 4 Denmark 17 3 England 40 21 Finland 5 1 Ireland 37 16 Italy 19 8 North Ireland 23 14 Norway 6 3 Portugal 7 3 Scotland 53 31 United States 34 24 Example – Scatterplot

  11. Example – Scatterplot

  12. Example – Scatterplot • The variables are interchangeable in this example. • In this example, Percent of Marijuana is being used as the explanatory variable (since it is on the x-axis). • Percent of Other Drugs is being used as the response since it is on the y-axis.

  13. Example - Scatterplot • The form is linear • The strength is fairly strong • The direction is positive since larger values on the x-axis yield larger values on the y-axis

  14. Example - Scatterplot • Negative association • Outside temperature and amount of natural gas used

  15. Correlation • The strength of the linear relationship between two quantitative variables can be described numerically • This numerical method is called correlation • Correlation is denoted by r

  16. Correlation • A way to measure the strength of the linear relationship between two quantitative variables.

  17. Correlation • Steps to calculate correlation: • Calculate the mean of x and y • Calculate the standard deviation for x and y • Calculate • Plug all numbers into formula

  18. Correlation

  19. Calculating r. • Femur (x) 38 56 59 63 74 • Humerus (y) 41 63 70 72 84 • Set up a table with columns for x, y, , , , , and

  20. x y 38 41 -20 -25 400 625 500 56 63 -2 -3 4 9 6 59 70 1 4 1 16 4 63 72 5 6 25 36 30 74 84 16 18 256 324 288 290 330 0 0 686 1010 828 Calculating r.

  21. Calculating r • Recall: • So,

  22. Calculating r • Recall: • So,

  23. Calculating r. • Put everything into the formula:

  24. Properties of r • r has no units (i.e., just a number) • Measures the strength of a LINEAR association between two quantitative variables • If the data have a curvilinear relationship, the correlation may not be strong even if the data follow the curve very closely.

  25. Properties of r • r always ranges in values from –1 to 1 • r = 1 indicates a straight increasing line • r = -1 indicates a straight decreasing line • r = 0 indicates no LINEAR relationship • As r moves away from 0, the linear relationship between variables is stronger

  26. Properties of r • Changing the scale of x or y will not change the value of r • Not resistant to outliers • Strong correlation ≠ Causation • Strong linear relationship between two variables is NOT proof of a causal relationship!

  27. Reading JMP Output • The following is some output from JMP where I considered Blood Alcohol Content and Number of Beers. The explanatory variable is the number of beers. Blood alcohol content is the response variable.

  28. Reading JMP Output

  29. Reading JMP Output Summary of Fit

  30. Reading JMP Output • RSquare = r2 • This means • I know this is positive because the scatterplot has a positive direction. • The Mean of the Response is the mean of the y’s or

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