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Objectives

Objectives. Chapter 4: Displaying Quantitative Data What are some ways in which we can effectively display quantitative data? What can we learn about a distribution from its display?. NJCCCS 4.5.12.C.1. Objectives. Chapter 4: Displaying Quantitative Data How do we describe a distribution?

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Objectives

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  1. Objectives • Chapter 4: Displaying Quantitative Data • What are some ways in which we can effectively display quantitative data? • What can we learn about a distribution from its display? NJCCCS 4.5.12.C.1

  2. Objectives • Chapter 4: Displaying Quantitative Data • How do we describe a distribution? • What are we looking for when comparing distributions? NJCCCS 4.5.12.C.1

  3. A dotplot is a simple display. It just places a dot along an axis for each case in the data. Let’s turn to the worksheet… Dotplots

  4. Histograms • First, slice up the entire span of values covered by the quantitative variable into equal-width piles called bins. • The bins and the counts in each bin give the distribution of the quantitative variable.

  5. Histograms • A histogramplots the bin counts as the heights of bars (like a bar chart). • Here is a histogram of the monthly price changes in Enron stock: Let’s create a histogram using the worksheet…

  6. Histograms • A relative frequency histogram displays the percentage of cases in each bin instead of the count.

  7. Stem-and-Leaf Displays • Stem-and-leaf displays show the distribution of a quantitative variable, like histograms do, while preserving the individual values. • Stem-and-leaf displays contain all the information found in a histogram and, when carefully drawn, satisfy the area principle and show the distribution.

  8. Stem-and-Leaf Displays pulse rates of 24 women at a health clinic.

  9. Constructing a Stem-and-Leaf Display • First, cut each data value into leading digits (“stems”) and trailing digits (“leaves”). • Use the stems to label the bins. • Use only one digit for each leaf—either round or truncate the data values to one decimal place after the stem.

  10. Shape, Center, and Spread • When describing a distribution, make sure to always tell about three things: shape, center, and spread…

  11. What is the Shape of the Distribution? • Does the histogram have a single, central hump or several separated bumps? • Is the histogram symmetric? • Do any unusual features stick out?

  12. Humps and Bumps • Does the histogram have a single, central hump or several separated bumps? • Humps in a histogram are called modes. • A histogram with one main peak is dubbed unimodal; histograms with two peaks are bimodal; histograms with three or more peaks are called multimodal.

  13. A bimodal histogram has two apparent peaks: Humps and Bumps (cont.)

  14. A histogram that doesn’t appear to have any mode and in which all the bars are approximately the same height is called uniform: Humps and Bumps (cont.)

  15. Symmetry • Is the histogram symmetric? • If you can fold the histogram along a vertical line through the middle and have the edges match pretty closely, the histogram is symmetric.

  16. Symmetry (cont.) • The (usually) thinner ends of a distribution are called the tails. If one tail stretches out farther than the other, the histogram is said to be skewed to the side of the longer tail. • In the figure below, the histogram on the left is said to be skewed left, while the histogram on the right is said to be skewed right.

  17. Anything Unusual? • Do any unusual features stick out? • Sometimes it’s the unusual features that tell us something interesting or exciting about the data. • You should always mention any stragglers, or outliers, that stand off away from the body of the distribution. • Are there any gaps in the distribution? If so, we might have data from more than one group.

  18. Anything Unusual? (cont.) • The following histogram has outliers—there are three cities in the leftmost bar:

  19. Where is the Center of the Distribution? • If you had to pick a single number to describe all the data what would you pick? • It’s easy to find the center when a histogram is unimodal and symmetric—it’s right in the middle. • On the other hand, it’s not so easy to find the center of a skewed histogram or a histogram with more than one mode. • For now, we will “eyeball” the center of the distribution. In the next chapter we will find the center numerically.

  20. How Spread Out is the Distribution? • Variation matters, and Statistics is about variation. • Are the values of the distribution tightly clustered around the center or more spread out? • In the next two chapters, we will talk about spread… Stay Tuned

  21. Comparing Distributions • Often we would like to compare two or more distributions instead of looking at one distribution by itself. • When looking at two or more distributions, it is very important that the histograms have been put on the same scale. Otherwise, we cannot really compare the two distributions. • When we compare distributions, we talk about the shape, center, and spread of each distribution.

  22. Comparing Distributions (cont.) • Compare the following distributions of ages for female and male heart attack patients:

  23. Timeplots: Order, Please! • For some data sets, we are interested in how the data behave over time. In these cases, we construct timeplots of the data.

  24. *Re-expressing Skewed Data to Improve Symmetry Figure 4.11

  25. *Re-expressing Skewed Data to Improve Symmetry (cont.) • One way to make a skewed distribution more symmetric is to re-express or transform the data by applying a simple function (e.g., logarithmic function). • Note the change in skewness from the raw data (Figure 4.11) to the transformed data (Figure 4.12): Figure 4.12

  26. What Can Go Wrong? • Don’t make a histogram of a categorical variable—bar charts or pie charts should be used for categorical data. • Don’t look for shape, center, and spread of a bar chart.

  27. What Can Go Wrong? (cont.) • Don’t use bars in every display—save them for histograms and bar charts. • Below is a badly drawn timeplot and the proper histogram for the number of eagles sighted in a collection of weeks:

  28. What Can Go Wrong? (cont.) • Choose a bin width appropriate to the data. • Changing the bin width changes the appearance of the histogram:

  29. Avoid inconsistent scales, either within the display or when comparing two displays. Label clearly so a reader knows what the plot displays. Good intentions, bad plot: What Can Go Wrong? (cont.)

  30. What have we learned? • We’ve learned how to make a picture for quantitative data to help us see the story the data have to Tell. • We can display the distribution of quantitative data with a histogram, stem-and-leaf display, or dotplot. • Tell about a distribution by talking about shape, center, spread, and any unusual features. • We can compare two quantitative distributions by looking at side-by-side displays (plotted on the same scale). • Trends in a quantitative variable can be displayed in a timeplot.

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