1. Descriptive Statistics Measures of Center
Essentials
Notation
Measures of Center
Mean
Median
Mode
Mid-range
Example
Which to Use: Mean vs. Median vs. Mode
Additional Topics (not addressed)

2. Essentials: Measures of Center (The great mean vs. median conundrum.)
Be able to identify the characteristics of the median, mean and mode, and to which types of data each applies.
Be able to calculate the median, mean and mode, as appropriate, for a set of data.
Affected by vs. resistant to extreme values. What are the implications for the mean and median?.

3. Some Notation  denotes the addition of a set of values
X (capital)is the variable usually used to represent the individual data values
xi (small letter) represents a single value of a variable from the first value, x1, to the last value xn
n represents the number of data values in a sample
N represents the number of data values in a population

4. Measures of Center Measures of Central Tendency
Indicate where the center or most typical value of a data set lies
Are often thought of as averages
Include the Mean, Median, Mode, and Midrange

5. The Mean (Arithmetic) The Formula: The “average” of a set of data.
There are several types of means including:
Harmonic mean for rates of change, such as speed: n/sigma(1/x);
Geometric mean for average rates of change or growth such as interest: nth root of (x*y*z) where n = number of values;
Quadratic mean for power (voltage, etc.): Sqrt of ((sum x2)/n)
The “average” of a set of data.
Is the sum of the observations divided by the number of observations.
Is used only with quantitative data.

6. Population Mean vs. Sample Mean
A Sample Mean is represented by the lower case letter x with a bar above it (called x-bar)
A Population Mean is represented by the lower case Greek letter m (mu)

7. Median The middle observation in a set of data.
Divides the data such that 50% of the observations lie below the median and 50% lie above it.
Is used only with quantitative data.
To obtain the median, the data must be placed in increasing order.

8. MEDIAN: The Formula First: Arrange the scores in increasing order.
Second: Apply the formula (n+1)/2. (Where n is the number of data values.)
If there is an EVEN number of scores, the Median lies between the two middle scores.
e.g: 1, 2, 8, 15 => Median is (n+1)/2 = (4+1)/2 = 2.5 (position). So, the Median is the data value that lies 1/2 way between the second and third data values. Here that value would be 5.
If there is an ODD number of scores, the middle score is the value of the Median.
e.g: 1, 3, 6 => Median is (n+1)/2 = (3+1)/2 = 2 (position). So, the Median is value in the second position of the list of values. Here the second value is the number 3.
Remember, the formula computes a position, not a data value.

9. Calculating a Median:
Determine the median for the following backpack weights:
Backpack weights (lb): 10, 14, 12, 18, 32, 15, 22, 19, 23, 61.

10. MODE: The Formula The most frequently occurring score in a data set.
Obtain the frequency of each value.
A Frequency Table based upon Single-Value Grouping or a Dot Plot would display this information.
Used with both qualitative and quantitative data.
It is the only measure of center for qualitative data.
There may be more than one Mode
If there are two modes, the data set is bimodal.
If there are more than two modes, the data set is multimodal.
If there is the same number of each value, then there is no mode

11. Midrange
The Midrange is a measure of center of a distribution. It indicates the value midway between the highest and lowest values in a data set. To find the midrange.
Highest Value + Lowest Value 2

12. Example: Comparing the Mean, Median, and Mode
Find the mean, median, and mode of the sample ages of a class shown. Which measure of central tendency best describes a typical entry of this data set? Are there any outliers?
Ages in a class 20 21 22 23 24 65
Source: Larson/Farber 4th ed.

13. Solution: Comparing the Mean, Median, and Mode
Ages in a class 20 21 22 23 24 65
Mean:
Median:
Mode:
20 years (the entry occurring with the greatest frequency)
Source: Larson/Farber 4th ed.

14. Solution: Comparing the Mean, Median, and Mode
Mean ≈ 23.8 yrs. Median = 21.5 yrs. Mode = 20 yrs.
The mean takes every entry into account, but is influenced by the outlier of 65.
The median here was determined by taking the middle two entries into account, and it is not affected by the outlier.
In this case the mode exists, but it doesn't appear to represent a typical entry.
Source: Larson/Farber 4th ed.

15. Solution: Comparing the Mean, Median, and Mode
Sometimes a graphical comparison can help you decide which measure of central tendency best represents a data set.
In this case, it appears that the median best describes the data set.
Source: Larson/Farber 4th ed.

16. Mean vs. Median vs. Mode Which is the best Measure of Center????
Is sensitive to the influence of extreme scores (outliers), which will “pull” the mean away from the center.
Involves ALL data values in the calculation
MEDIAN:
Is resistant to the influence of extreme values.
Only uses One or Two points in its calculation.
MODE:
May not be anywhere near the center of the data.
Not really aimed at finding the middle of the data.
Is the ONLY “Measure of Center” for Qualitative Data.

17. Additional Topics

18. Weighted Means
Weighted Mean – a mean computed with different scores assigned different weights. To find the weighted mean

19. Weighted Example: Finding a Weighted Mean
You are taking a class in which your grade is determined from five sources: 50% from your test mean, 15% from your midterm, 20% from your final exam, 10% from your computer lab work, and 5% from your homework. Your scores are 86 (test mean), 96 (midterm), 82 (final exam), 98 (computer lab), and 100 (homework). What is the weighted mean of your scores? If the minimum average for an A is 90, did you get an A?
Source: Larson/Farber 4th ed.

20. Solution: Finding a Weighted Mean
Source
Score, x
Weight, w
x∙w
Test Mean 86
0.50
86(0.50)= 43.0
Midterm 96
0.15
96(0.15) = 14.4
Final Exam 82
0.20
82(0.20) = 16.4
Computer Lab 98
0.10
98(0.10) = 9.8
Homework
100
0.05
100(0.05) = 5.0
Σw = 1
Σ(x∙w) = 88.6
Your weighted mean for the course is You did not get an A.
Source: Larson/Farber 4th ed.

21. Weighted Means Example
Calculating a GPA.
Given the following four grades, calculate the semester GPA.
Statistics A (of course; 3 CrHrs; numeric value for an A = 4)
History B (3 CrHr; B = 3)
Physics C (3 CrHr; C = 2)
Physical Education C (1 CrHr)
The grade numeric equivalents are the x values. The credit hour values are the weights.
Calculate the student’s GPA.

22. Finding a Mean From a Frequency Table (Grouped Data)
When we view data in a frequency table, it is impossible to know the exact values falling in a particular class. To find this value, obtain the product of each frequency and class midpoint (here “x”), add the products, and then divide by the sum of the frequencies.

23. Finding the Mean of a Frequency Distribution
In Words In Symbols
Find the midpoint of each class.
Find the sum of the products of the midpoints and the frequencies.
Find the sum of the frequencies.
Find the mean of the frequency distribution.
Source: Larson/Farber 4th ed.

24. Example: Find the Mean of a Frequency Distribution
Use the frequency distribution to approximate the mean number of minutes that a sample of Internet subscribers spent online during their most recent session.
Class
Midpoint
Frequency, f
7 – 18
12.5 6
19 – 30
24.5 10
31 – 42
36.5 13
43 – 54
48.5 8
55 – 66
60.5 5
67 – 78
72.5
79 – 90
84.5 2
Source: Larson/Farber 4th ed.

25. Example: Find the Mean of a Frequency Distribution
Use the frequency distribution to approximate the mean number of minutes that a sample of Internet subscribers spent online during their most recent session.
Class
Midpoint, x
Frequency, f
(x∙f)
7 – 18
12.5 6
12.5∙6 = 75.0
19 – 30
24.5 10
24.5∙10 = 245.0
31 – 42
36.5 13
36.5∙13 = 474.5
43 – 54
48.5 8
48.5∙8 = 388.0
55 – 66
60.5 5
60.5∙5 = 302.5
67 – 78
72.5
72.5∙6 = 435.0
79 – 90
84.5 2
84.5∙2 = 169.0
n = 50
Σ(x∙f) =
Source: Larson/Farber 4th ed.

26. End of Slides