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STAT 101: Day 5 Descriptive Statistics II 1/30/12. One Quantitative Variable (continued) Quantitative with a Categorical Variable Two Quantitative Variables. Section 2.3, 2.4, 2.5. Professor Kari Lock Morgan Duke University. Clicker Registration.
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STAT 101: Day 5 Descriptive Statistics II 1/30/12 • One Quantitative Variable (continued) • Quantitative with a Categorical Variable • Two Quantitative Variables • Section 2.3, 2.4, 2.5 • Professor Kari Lock Morgan • Duke University
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Measures of Center m=$1,250,000 x=$2,210,000 Mean is “pulled” in the direction of skewness
Standard Deviation • The sample standard deviation, s, measures the spread of a distribution. The larger s is, the more spread out the distribution is Standard deviation is always ≥ 0. R: sd()
Standard Deviation Both of these distributions are bell-shaped
The 95% Rule • If a distribution is symmetric and bell-shaped, then approximately 95% of the data values will lie within 2 standard deviations of the mean
The 95% Rule The standard deviation for hours of sleep per night is closest to • ½ • 1 • 2 • 4 • I have no idea
z-score • A z-score is unit-free measure of extremity of a data point. It tells us how many standard deviations away from the mean a value is • Values farther from 0 are more extreme • 95% of all z-scores fall between -2 and 2
z-score Which is better, an ACT score of 28 or a combined SAT score of 2100? • ACT: mean = 21, sd = 5 • SAT: mean = 1500, sd = 325 • Assume ACT scores and SAT scores have approximately symmetric and bell-shaped distributions (a) ACT score of 28 (b) SAT score of 2100 (c) I don’t know
Other Measures of Location • Maximum = largest data value • Minimum = smallest data value • Quartiles: • Q1 = median of the values below m. • Q3 = median of the values above m.
Min Q1 m Q3 Max 25% 25% 25% 25% Five Number Summary • Five Number Summary: R: summary()
Percentile • The Pthpercentileis the value of a quantitative variable which is greater than P percent of the data • We already used z-scores to determine whether an SAT score of 2100 or an ACT score of 28 is better • We could also have used percentiles: • ACT score of 28: 91st percentile • SAT score of 2100: 97th percentile
Min Q1 m Q3 Max 25% 25% 25% 25% Five Number Summary • Five Number Summary: 50th percentile 75th percentile 100th percentile 0th percentile 25th percentile
Five Number Summary > summary(study_hours) Min. 1st Qu. Median 3rd Qu. Max. 2.00 10.00 15.00 20.00 69.00 The distribution of number of hours you spend studying each week is (a) Symmetric (b) Right-skewed (c) Left-skewed (d) Impossible to tell
Measures of Spread • Range = Max – Min • Interquartile Range (IQR) = Q3 – Q1 • Is the range resistant to outliers? • Yes • No • Is the IQR resistant to outliers? • Yes • No
Outliers • Outliers can be informally identified by looking at a plot, but one rule of thumb for identifying outliers is data values more than 1.5 IQRs beyond the quartiles • A data value is an outlier if it is Smaller than Q1 – 1.5(IQR) or Larger than Q3 + 1.5(IQR)
Boxplot Outliers • Lines (“whiskers”) extend from each quartile to the most extreme value that is not an outlier Q3 Median Q1 R: boxplot(study_hours, ylab=“Hours spent studying”)
Boxplot Which boxplot goes with the histogram of waiting times for the bus? (a) (b) (c)
Summary: One Quantitative Variable • Summary Statistics • Center: mean, median • Spread: standard deviation, range, IQR • Percentiles • 5 number summary • Visualization • Dotplot • Histogram • Boxplot • Other concepts • Shape: symmetric, skewed, bell-shaped • Outliers, resistance • z-scores
Quantitative and Categorical Relationships • Boxplots are particularly useful for comparing distributions of a quantitative variable across different levels of a categorical variable
Side-by-Side Boxplots • Do students whose parents had more of an education have higher GPAs? boxplot(gpa~parent_degree, ylab="GPA", xlab="Parents' Highest Degree")
Side-by-Side Boxplots • Does GPA differ by major?
Side-by-Side Boxplots • Do students who’ve had AP statistics do better in STAT 101? • NO!
Quantitative Statistics by a Categorical Variable • Any of the statistics we use for a quantitative variable can be looked at separately for each level of a categorical variable • Mean hours per week spent studying by major:
Summary: One Quantitative and One Categorical • Summary Statistics • Any summary statistics for quantitative variables, broken down by each level of the categorical variable • Visualization • Side-by-side boxplots
Scatterplot • Ascatterplotis a graph of the relationship between two quantitative variables. Each dot represents one case. R: plot(study_hours, gpa)
Direction of Association • A positive associationmeans that values of one variable tend to be higher when values of the other variable are higher • A negative associationmeans that values of one variable tend to be lower when values of the other variable are higher • Two variables are not associated if knowing the value of one variable does not give you any information about the value of the other variable
Cars Data - Handout • Quantitative Variables: • Weight (pounds) • City MPG • Fuel capacity (gallons) • Page number (in Consumer Reports) • Time to go ¼ mile (in seconds) • Acceleration time from 0 to 60 mph • Relationships • Weight vs. CityMPG • Weight vs. FuelCapacity • PageNum vs. Fuel Capacity • Weight vs. QtrMile • Acc060 vs. QtrMile • CityMPG vs. QtrMile
Correlation • The sample correlation, r, measures the strength and direction of linear association between two quantitative variables sX: sample standard deviation of X sY: sample standard deviation of Y R: cor(X,Y)
Car Correlations (-.91) (.89) (-.45) (.51) (.99) (-.08) What are the properties of correlation?
Correlation • -1 ≤ r ≤ 1 • positive association: r > 0 • negative association: r < 0 • no linear association: r 0 • The closer r is to ±1, the stronger the linear association • r does not depend on the units of measurement • The correlation between X and Y is the same as the correlation between Y and X