Frequency Polygons Graphs of Frequency Distributions Frequency Polygon
Frequency Polygons
Graphs of Frequency Distributions Frequency Polygon • A line graph that emphasizes the continuous change in frequencies. • Use the same horizontal and vertical scales that were used in the histogram labeled with class midpoints. • The graph should begin and end on the horizontal axis Extend the left side one class width before the first class midpoint Extend the right side one class width after the last class midpoint frequency • • data values © 2012 Pearson Education, Inc. All rights reserved. 2 of 149
Do Now • Use the following data set to find the (a) range, (b) class width, (c) Lower class limits and (d) Upper class limits. • • Newspaper Reading Times Number of classes: 5 7 39 13 9 25 8 22 0 2 18 2 30 7 35 12 15 8 6 5 29 0 11 39 16 15
Example: Frequency Polygon Construct a frequency polygon for the GPS navigators frequency distribution. Class Midpoint Frequency, f 59– 114 86. 5 5 115– 170 142. 5 8 171– 226 198. 5 6 227– 282 254. 5 5 283– 338 310. 5 2 339– 394 366. 5 1 395– 450 422. 5 3 © 2012 Pearson Education, Inc. All rights reserved. 4 of 149
Solution: Frequency Polygon The graph should begin and end on the horizontal axis, so extend the left side to one class width before the first class midpoint and extend the right side to one class width after the last class midpoint. You can see that the frequency of GPS navigators increases up to $142. 50 and then decreases. © 2012 Pearson Education, Inc. All rights reserved. 5 of 149
• Your turn: Use the frequency distribution below to construct a frequency polygon that represents the ages of the 50 richest people. Describe any patterns.
Do Now • Create a Frequency Polygon for the following set of data: Class Frequency, ƒ 20 -30 19 31 -41 43 42 -52 68 53 -63 69 64 -74 74 75 -85 68 86 -96 24
Example: • Use the data to construct (a) an expanded frequency distribution, (b) a frequency histogram and (c) a frequency polygon • Pulse Rates • • Number of classes: 6 Data Set: Pulse rates of students in a class 68 105 95 80 90 100 75 70 84 98 102 70 65 88 90 75 78 94 110 120 95 80 76 108
Graphing Quantitative Data Sets Stem-and-leaf plot • Each number is separated into a stem and a leaf. • Similar to a histogram. • Still contains original data values. • Should always include a key to identify the values of the data. 26 Data: 21, 25, 26, 27, 28, 30, 36, 45 © 2012 Pearson Education, Inc. All rights reserved. 2 1 5 5 67 8 3 06 6 4 5 9 of 149
Example: Constructing a Stem-and-Leaf Plot The following are the numbers of text messages sent last week by the cellular phone users on one floor of a college dormitory. Display the data in a stem-and-leaf plot. 155 159 118 139 129 112 144 108 122 126 129 122 78 148 105 145 126 116 130 114 122 112 142 126 121 109 140 126 119 113 117 118 109 119 133 126 123 145 121 134 124 119 132 133 124 147 © 2012 Pearson Education, Inc. All rights reserved. 10 of 149
Solution: Constructing a Stem-and-Leaf Plot 155 159 118 139 129 112 144 108 122 126 129 122 78 148 105 145 126 116 130 114 122 112 142 126 121 109 140 126 119 113 117 118 109 119 133 126 123 145 121 134 124 119 132 133 124 147 • The data entries go from a low of 78 to a high of 159. • Use the rightmost digit as the leaf. § For instance, 78 = 7 | 8 and 159 = 15 | 9 • List the stems, 7 to 15, to the left of a vertical line. • For each data entry, list a leaf to the right of its stem. © 2012 Pearson Education, Inc. All rights reserved. 11 of 149
Solution: Constructing a Stem-and-Leaf Plot Include a key to identify the values of the data. From the display, you can conclude that more than 50% of the cellular phone users sent between 110 and 130 text messages. © 2012 Pearson Education, Inc. All rights reserved. 12 of 149
Your turn • Use a stem-and-leaf plot to display the data. The data represent the scores of a biology class on a midterm exam. 75 83 85 92 90 94 80 68 87 75 67 91 82 79 88 95 95 87 91 76 73 91 80 85
Graphing Quantitative Data Sets Dot plot • Each data entry is plotted, using a point, above a horizontal axis. • Allows you to see how data are distributed, determine specific data entries, and identify unusual data values. Data: 21, 25, 26, 27, 28, 30, 36, 45 26 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 © 2012 Pearson Education, Inc. All rights reserved. 14 of 149
Example: Constructing a Dot Plot Use a dot plot organize the text messaging data. 155 159 118 139 129 112 144 108 122 126 129 122 78 148 105 145 126 116 130 114 122 112 142 126 121 109 140 126 119 113 117 118 109 119 133 126 123 145 121 134 124 119 132 133 124 147 • So that each data entry is included in the dot plot, the horizontal axis should include numbers between 70 and 160. • To represent a data entry, plot a point above the entry's position on the axis. • If an entry is repeated, plot another point above the previous point. © 2012 Pearson Education, Inc. All rights reserved. 15 of 149
Solution: Constructing a Dot Plot 155 159 118 139 129 112 144 108 122 126 129 122 78 148 105 145 126 116 130 114 122 112 142 126 121 109 140 126 119 113 117 118 109 119 133 126 123 145 121 134 124 119 132 133 124 147 From the dot plot, you can see that most values cluster between 105 and 148 and the value that occurs the most is 126. You can also see that 78 is an unusual data value. © 2012 Pearson Education, Inc. All rights reserved. 16 of 149
Your Turn • Make a dot plot display of the given data set. • 64 52 55 Highest Paid CEO’s 74 50 56 55 59 48 55 62 58 62 64 64 63 57 60 50 61 60 67 49 57 51 63 59 62 50 60
Graphing Paired Data Sets • Each entry in one data set corresponds to one entry in a second data set. • Graph using a scatter plot. • The ordered pairs are graphed as points in a coordinate plane. • Used to show the relationship between two quantitative variables. y x © 2012 Pearson Education, Inc. All rights reserved. 18 of 149
Example: Interpreting a Scatter Plot The British statistician Ronald Fisher introduced a famous data set called Fisher's Iris data set. This data set describes various physical characteristics, such as petal length and petal width (in millimeters), for three species of iris. The petal lengths form the first data set and the petal widths form the second data set. (Source: Fisher, R. A. , 1936) © 2012 Pearson Education, Inc. All rights reserved. 19 of 149
Example: Interpreting a Scatter Plot As the petal length increases, what tends to happen to the petal width? Each point in the scatter plot represents the petal length and petal width of one flower. © 2012 Pearson Education, Inc. All rights reserved. 20 of 149
Solution: Interpreting a Scatter Plot Interpretation From the scatter plot, you can see that as the petal length increases, the petal width also tends to increase. © 2012 Pearson Education, Inc. All rights reserved. 21 of 149
Example Scatter Plot • The lengths of employment and the salaries of 10 employees are listed in the table below. Graph the data using a scatter plot. What can you conclude? Length of employment (in years) Salary (in dollars) 5 32, 000 4 32, 500 8 40, 000 4 27, 350 2 25, 000 10 43, 000 7 41, 650 6 39, 225 9 45, 100 3 28, 000
Your turn • Use a scatter plot to display the data shown in the table. • The data represent the number of hours worked and the hourly wages (in dollars) for a sample of 12 production workers. Describe any trends shown. Hours Hourly wage 33 12. 16 37 9. 98 34 10. 79 40 11. 71 35 11. 8 33 11. 51 40 13. 65 33 12. 05 28 10. 54 45 10. 33 37 11. 57 28 10. 17
Your turn Solution Example • Use a scatter plot to display the data shown in the table. The data represent the number of hours worked and the hourly wages (in dollars) for a sample of 12 production workers. Describe any trends shown. Number of hours worked and the hourly wages 14 13 Hourly Wages • 12 11 10 9 8 25 30 35 Hours worked 40 45 50
Graphing Paired Data Sets Time Series • Data set is composed of quantitative entries taken at regular intervals over a period of time. e. g. , The amount of precipitation measured each day for one month. • Use a time series chart to graph. • Data on Vertical Axis • Time on Horizontal Axis. Quantitative data • time © 2012 Pearson Education, Inc. All rights reserved. 25 of 149
Example: Constructing a Time Series Chart The table lists the number of cellular telephone subscribers (in millions) for the years 1998 through 2008. Construct a time series chart for the number of cellular subscribers. (Source: Cellular Telecommunication & Internet Association) © 2012 Pearson Education, Inc. All rights reserved. 26 of 149
Solution: Constructing a Time Series Chart • Let the horizontal axis represent the years. • Let the vertical axis represent the number of subscribers (in millions). • Plot the paired data and connect them with line segments. • Describe any trends. © 2012 Pearson Education, Inc. All rights reserved. 27 of 149
Solution: Constructing a Time Series Chart The graph shows that the number of subscribers has been increasing since 1998, with greater increases recently. © 2012 Pearson Education, Inc. All rights reserved. 28 of 149
Your Turn • Use the table from the previous example to construct a time series chart for subscribers’ average monthly bill (in dollars) for the years 1998 through 2008. Describe any trends.
Example Solution • We can see that the average monthly bill rose gradually from 1998 to 2004 and then hovered around $50 after. AVERAGE MONTHLY BILL 1998 -2008 Average monthly bill 55 50 45 40 35 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 Year
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