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42.1: Representing Data Graphically

  • Page ID
    40874
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    Lesson

    Let's represent data with dot plots and bar graphs.

    Exercise \(\PageIndex{1}\): Curious about Caps

    Clare collects bottle caps and keeps them in plastic containers.

    clipboard_ef334e4f2c8f70beb31bef73adf0fccf2.png
    Figure \(\PageIndex{1}\)

    Write one statistical question that someone could ask Clare about her collection. Be prepared to explain your reasoning.

    Exercise \(\PageIndex{2}\): Estimating Caps

    1. Write down the statistical question your class is trying to answer.
    2. Look at the dot plot that shows the data from your class. Write down one thing you notice and one thing you wonder about the dot plot.
    3. Use the dot plot to answer the statistical question. Be prepared to explain your reasoning.

    Exercise \(\PageIndex{3}\): Been There, Done That!

    Priya wants to know if basketball players on a men’s team and a women’s team have had prior experience in international competitions. She gathered data on the number of times the players were on a team before 2016.

    men's team

    \(3\qquad 0\qquad 0\qquad 0\qquad 0\qquad 1\qquad 0\qquad 0\qquad 0\qquad 0\qquad 0\qquad 0\)

    women's team

    \(2\qquad 3\qquad 3\qquad 1\qquad 0\qquad 2\qquad 0\qquad 1\qquad 1\qquad 0\qquad 3\qquad 1\)

    1. Did Priya collect categorical or numerical data?
    2. Organize the information on the two basketball teams into these tables.

    Men's Basketball Team Players

    number of prior competitions frequency (number)
    \(0\)
    \(1\)
    \(2\)
    \(3\)
    \(4\)
    Table \(\PageIndex{1}\)

    Women's Basketball Team Players

    number of prior competitions frequency (number)
    \(0\)
    \(1\)
    \(2\)
    \(3\)
    \(4\)
    Table \(\PageIndex{2}\)
    1. Make a dot plot for each table.

    Men’s Basketball Team Players

    clipboard_e59ef7fafc7df2f8c342475914c018b78.png
    Figure \(\PageIndex{2}\)

    Women’s Basketball Team Players

    clipboard_ebd797d4c80944b23563573aac0c4926e.png
    Figure \(\PageIndex{3}\)
    1. Study your dot plots. What do they tell you about the competition participation of:
      1. the players on the men’s basketball team?
      2. the players on the women’s basketball team?
    2. Explain why a dot plot is an appropriate representation for Priya’s data.

    Are you ready for more?

    Combine the data for the players on the men’s and women’s teams and represent it as a single dot plot. What can you say about the repeat participation of the basketball players?

    clipboard_e1c563b7dec58c48453354fdc84e177f3.png
    Figure \(\PageIndex{4}\)

    Exercise \(\PageIndex{4}\): Favorite Summer Sports

    Kiran wants to know which three summer sports are most popular in his class. He surveyed his classmates on their favorite summer sport. Here are their responses.

    \(\begin{array}{llll}{\text{swimming}}&{\text{gymnastics}}&{\text{track and field}}&{\text{volleyball}} \\ {\text{swimming}}&{\text{swimming}}&{\text{diving}}&{\text{track and field}} \\ {\text{gymnastics}} &{\text{basketball}} &{\text{basketball}} &{\text{volleyball}} \\ {\text{track and field}} &{\text{track and field}} &{\text{volleyball}} &{\text{gymnastics}} \\ {\text{diving}} &{\text{gymnastics}} &{\text{volleyball}} &{\text{rowing}} \\ {\text{track and field}} &{\text{track and field}} &{\text{soccer}} &{\text{swimming}} \\ {\text{gymnastics}} &{\text{track and field}} &{\text{swimming}} &{\text{rowing}} \\ {\text{diving}} & {\text{soccer}} &{}&{}\end{array}\)

    1. Did Kiran collect categorical or numerical data?
    2. Organize the responses in a table to help him find which summer sports are most popular in his class.
      sport frequency
      Table \(\PageIndex{3}\)
    3. Represent the information in the table as a bar graph.
    clipboard_e5f7e57be60a84e15ec853a085d3cacdd.png
    Figure \(\PageIndex{5}\)
      1. How can you use the bar graph to find how many classmates Kiran surveyed?
      2. Which three summer sports are most popular in Kiran’s class?
      3. Use your bar graph to describe at least one observation about Kiran’s classmates’ preferred summer sports.
    1. Could a dot plot be used to represent Kiran’s data? Explain your reasoning.

    Summary

    When we analyze data, we are often interested in the distribution, which is information that shows all the data values and how often they occur.

    In a previous lesson, we saw data about 10 dogs. We can see the distribution of the dog weights in a table such as this one.

    weight in kilograms frequency
    \(6\) \(1\)
    \(7\) \(3\)
    \(10\) \(2\)
    \(32\) \(1\)
    \(35\) \(2\)
    \(36\) \(1\)
    Table \(\PageIndex{4}\)

    The term frequency refers to the number of times a data value occurs. In this case, we see that there are three dogs that weigh 7 kilograms, so “3” is the frequency for the value “7 kilograms.”

    Recall that dot plots are often used to to represent numerical data. Like a frequency table, a dot plot also shows the distribution of a data set. This dot plot, which you saw in an earlier lesson, shows the distribution of dog weights.

    clipboard_e738a6133db3e0658bf0599b2161d17f6.png
    Figure \(\PageIndex{6}\): A dot plot for dog weights in kilograms. The numbers 5 through 40, in increments of 5, are indicated. The data are as follows: 6 kilograms, 1 dot. 7 kilograms, 3 dots. 10 kilograms, 2 dots. 32 kilograms, 1 dot. 35 kilograms, 2 dots. 36 kilograms, 1 dot.

    A dot plot uses a horizontal number line. We show the frequency of a value by the number of dots drawn above that value. Here, the two dots above the number 35 tell us that there are two dogs weighing 35 kilograms.

    The distribution of categorical data can also be shown in a table. This table shows the distribution of dog breeds.

    breed frequency
    pug \(9\)
    beagle \(9\)
    German shepherd \(12\)
    Table \(\PageIndex{5}\)

    We often represent the distribution of categorical data using a bar graph.

    clipboard_ebfbb62976726ecd10a2f8e84a53d59d8.png
    Figure \(\PageIndex{7}\): A bar graph. The categories pugs, beagles, and German shepherds are labeled on the horizontal axis. The numbers 0 through 4 are indicated on the vertical axis. The data represented by the bars are as follows: pugs, 3. beagles, 3. German shepherds, 4.

    A bar graph also uses a horizontal line. Above it we draw a rectangle (or “bar”) to represent each category in the data set. The height of a bar tells us the frequency of the category. There are 12 German shepherds in the data set, so the bar for this category is 12 units tall. Below the line we write the labels for the categories.

    In a dot plot, a data value is placed according to its position on the number line. A weight of 10 kilograms must be shown as a dot above 10 on the number line.

    In a bar graph, however, the categories can be listed in any order. The bar that shows the frequency of pugs can be placed anywhere along the horizontal line.

    Glossary Entries

    Definition: Distribution

    The distribution tells how many times each value occurs in a data set. For example, in the data set blue, blue, green, blue, orange, the distribution is 3 blues, 1 green, and 1 orange.

    Here is a dot plot that shows the distribution for the data set 6, 10, 7, 35, 7, 36, 32, 10, 7, 35.

    clipboard_e889a6c7b3c8ff3070c29f197834508c7.png
    Figure \(\PageIndex{8}\)

    Definition: Frequency

    The frequency of a data value is how many times it occurs in the data set.

    For example, there were 20 dogs in a park. The table shows the frequency of each color.

    color frequency
    white \(4\)
    brown \(7\)
    black \(3\)
    multi-color \(6\)
    Table \(\PageIndex{6}\)

    Practice

    Exercise \(\PageIndex{5}\)

    A teacher drew a line segment that was 20 inches long on the blackboard. She asked each of her students to estimate the length of the segment and used their estimates to draw this dot plot.

    clipboard_eee3e6528e9739d6978c2247fa3cdafb7.png
    Figure \(\PageIndex{9}\)
    1. How many students were in the class?
    2. Were students generally accurate in their estimates of the length of the line? Explain your reasoning.

    Exercise \(\PageIndex{6}\)

    Here are descriptions of data sets. Select all descriptions of data sets that could be graphed as dot plots.

    1. Class size for the classes at an elementary school
    2. Colors of cars in a parking lot
    3. Favorite sport of each student in a sixth-grade class
    4. Birth weights for the babies born during October at a hospital
    5. Number of goals scored in each of 20 games played by a school soccer team

    Exercise \(\PageIndex{7}\)

    Priya recorded the number of attempts it took each of 12 of her classmates to successfully throw a ball into a basket. Make a dot plot of Priya’s data.

    \(1\qquad 2\qquad 1\qquad 3\qquad 1\qquad 4\qquad 4\qquad 3\qquad 1\qquad 2\qquad 5\qquad 2\)

    Exercise \(\PageIndex{8}\)

    Solve each equation.

    1. \(9v=1\)
    2. \(1.37w=0\)
    3. \(1=\frac{7}{10}x\)
    4. \(12.1=12.1+y\)
    5. \(\frac{3}{5}+z=1\)

    (From Unit 6.1.4)

    Exercise \(\PageIndex{9}\)

    Find the quotients.

    1. \(\frac{2}{5}\div 2\)
    2. \(\frac{2}{5}\div 5\)
    3. \(2\div\frac{2}{5}\)
    4. \(5\div\frac{2}{5}\)

    (From Unit 4.3.2)

    Exercise \(\PageIndex{10}\)

    Find the area of each triangle.

    clipboard_e76d785f729823455a9cc94be37200c12.png
    Figure \(\PageIndex{10}\): Three triangles, labeled A, B, C. Triangle A, right, base = 5, height = 5. Triangle B, acute, base = 4, height = 3. Triangle C, obtuse, base 4, height= 4.

    (From Unit 1.3.3)


    42.1: Representing Data Graphically is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by LibreTexts.

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