1. Chapter 8 Random Variables
Probability Distributions
Discrete Random Variables
Continuous Random Variables
Binomial Probability Model

2. Randomness
A random variable is a numerical measurement of the outcome of a random phenomenon. It is a quantity that can take on different values.
Often, the randomness results from
selecting a random sample for a population or
performing a randomized experiment

3. Random Variable
Use letters near the end of the alphabet, such as x, to symbolize:
variables
a particular value of the random variable
Use a capital letter, such as X, to refer to the random variable itself.
Example: Flip a coin three times
X= number of heads in the 3 flips; defines the random variable
x=2; represents a possible value of the random variable

4. Probability Distribution
The probability distribution of a random variable specifies its possible values and their probabilities.
Note: It is the randomness of the variable that allows us to specify probabilities for the outcomes.

5. Probability Distribution of a Discrete Random Variable
A discrete random variable X takes a set of separate values (such as 0,1,2,…) as its possible outcomes.
Its probability distribution assigns a probability P(x) to each possible value x:
For each x, the probability P(x) falls between 0 and 1.
The sum of the probabilities for all the possible x
values equals 1.

6. Probability Distribution of a Discrete Random Variable
Let
X = the discrete random variable.
k = a number the discrete r.v. could assume.
P(X = k) is the probability that X equals k.
Probability distribution function (pdf) of X is a table or rule that assigns probabilities to possible values of X.

7. Example: Number of Courses
35% of students taking four courses,
45% taking five,
and remaining 20% are taking six courses.
Let X = number of courses a randomly selected student is taking
The probability distribution function of X can be given by:

8. Example: Number of Courses

9. Example: Number of Girls
Family has 3 children. Probability of a girl is ½. What are the probabilities of having 0, 1, 2, or 3 girls?
Sample Space: For each birth, write either B or G. There are eight possible arrangements of B and G for three births. These are the simple events.
Sample Space and Probabilities: The eight simple events are equally likely.
Random Variable X: number of girls in three births. For each simple event, the value of X is the number of G’s listed.

10. Example: Number of Girls
Probability Distribution Table

11. Example: Number of Girls
Probability Distribution Function for Number of Girls X:
Graph of the pdf of X:

12. Example: Number of Home Runs in a Game
What is the estimated probability of at least three home runs?
Table 8.1 Probability Distribution of Number of Home Runs in a Game for
San Francisco Giants

13. Example: Number of Home Runs in a Game
Table 8.1 Probability Distribution of Number of Home Runs in a Game for
San Francisco Giants
The probability of at least three home runs in a game is
P(3)+P(4)+P(5 or more)= =

14. Cumulative Distribution Function for a Discrete Random Variable
Cumulative distribution function (cdf) for a random variable X is a rule or table that provides the probabilities P(X ≤ k) for any real number k.
Cumulative probability = probability that X is less than or equal to a particular value.

15. Cumulative Distribution Function for Number of Girls

16. Example: A Mixture of Children
What is the probability that a family with 3 children will have at least one child of each sex?
If X = Number of Girls then either family has one girl and two boys (X = 1) or two girls and one boy (X = 2).
P(X = 1 or X = 2) = P(X = 1) + P(X = 2)
= 3/8 + 3/8 = 6/8 = 3/4
Probability distribution for number of girls:

17. Mean of a Discrete Probability Distribution
The mean of a probability distribution for a discrete random variable is:
where the sum is taken over all possible values of x.
The mean of a probability distribution is denoted by the parameter, .
The mean is a weighted average; values of x that are more likely receive greater weight P(x).

18. Expected Value of X
The mean of a probability distribution of a random variable X is also called the expected value of X.
The expected value reflects not what we’ll observe in a single observation, but rather what we expect for the average in a long run of observations.
It is not unusual for the expected value of a random variable to equal a number that is NOT a possible outcome.

19. Example: Number of Home Runs in a Game
Find the mean of this probability distribution.
Table 8.1 Probability Distribution of Number of Home Runs in a Game for
San Francisco Giants

20. Example: Number of Home Runs in a Game
The mean:
= 0(0.3889) + 1(0.3148) + 2(0.2222) + 3(0.0556) + 4(0.0185)
= 0 * P(0) + 1 * P(1) + 2 * P(2) + 3 * P(3) + 4 * P(4)
= 1

21. The Standard Deviation of a Discrete Random Variable
The standard deviation of a probability distribution, denoted by the parameter, , measures variability from the mean.
Larger values of correspond to greater spread.
Roughly, describes how far the random variable falls, on the average, from the mean of its distribution.

22. Standard Deviation of a Discrete Random Variable
The standard deviation of a random variable is roughly the average distance the random variable falls from its mean, or expected value, over the long run.
If X is a random variable with possible values x1, x2, x3, , occurring with probabilities p1, p2, p3, , and expected value E(X) = m, then

23. Example: Stability or Excitement?
Two plans for investing $ – which would you choose?

24. Example: Stability or Excitement?
Expected Value For Each Plan:
Plan 1: E(X ) = $5,000(.001) + $1,000(.005) + $0(.994) = $10.00
Plan 2: E(Y ) = $20(.3) + $10(.2) + $4(.5) = $10.00

25. Example: Stability or Excitement?
Variability for Each Plan:

26. Example: Stability or Excitement?
Plan 1: V(X ) = $29, and s = $172.92
Plan 2: V(X ) = $48.00 and s = $6.93
The possible outcomes for Plan 1 are much more variable. If you wanted to invest cautiously, you would choose Plan 2, but if you wanted to have the chance to gain a large amount of money, you would choose Plan 1.

27. More Examples From Midterm II Practice Sheet

28. Continuous Random Variable
A continuous random variable has an infinite continuum of possible values in an interval.
Examples are: time, age and size measures such as height and weight.
Continuous variables are usually measured in a discrete manner because of rounding.

29. Probability Distribution of a Continuous Random Variable
A continuous random variable has possible values that form an interval. Its probability distribution is specified by a curve.
Each interval has probability between 0 and 1.
The interval containing all possible values has probability equal to 1.

30. Probability Distribution of a Continuous Random Variable
Smooth curve approximation
Figure 8.2 Probability Distribution of Commuting Time. The area under the curve for values higher than 45 is Question: Identify the area under the curve represented by the probability that commuting time is less than 15 minutes, which equals 0.29.

31. Useful Probability Relationships

32. Useful Probability Relationships

33. Useful Probability Relationships

34. Useful Probability Relationships

35. Bell-Shaped Distributions
Probabilities for Bell – Shaped Distributions or Continuous Random Variables

36. Normal Distribution
The normal distribution is symmetric, bell-shaped and characterized by its mean and standard deviation .
The normal distribution is the most important distribution in statistics.
Many distributions have an approximately normal distribution.
The normal distribution also can approximate many discrete distributions well when there are a large number of possible outcomes.
Many statistical methods use it even when the data are not bell shaped.

37. Normal Distribution Normal distributions are Bell shaped
Symmetric around the mean
The mean ( ) and the standard deviation ( ) completely describe the density curve.
Increasing/decreasing moves the curve along the horizontal axis.
Increasing/decreasing controls the spread of the curve.

38. Normal Distribution
Within what interval do almost all of the men’s heights fall? Women’s height?
Figure 8.4 Normal Distributions for Women’s Height and Men’s Height. For each different combination of and values, there is a normal distribution with mean and standard deviation . Question: Given that = 70 and = 4, within what interval do almost all of the men’s heights fall?

39. Empirical Rule or 68-95-99.7 Rule for Any Normal Curve
≈ 68% of the observations fall within one standard deviation of the mean.
≈ 95% of the observations fall within two standard deviations of the mean.
≈ 99.7% of the observations fall within three standard deviations of the mean.
Figure 8.5 The Normal Distribution. The probability equals approximately 0.68 within 1 standard deviation of the mean, approximately 0.95 within 2 standard deviations, and approximately within 3 standard deviations. Question: How do these probabilities relate to the empirical rule?

40. Empirical Rule or 68 – 95 – 99.7% Rule

41. Example : % Rule
Heights of adult women can be approximated by a normal
distribution, inches; inches
Rule for women’s heights:
68% are between 61.5 and 68.5 inches
95% are between 58 and 72 inches
99.7% are between 54.5 and 75.5 inches

42. Z-Scores and the Standard Normal Distribution
The z-score for a value x of a random variable is the number of standard deviations that x falls from the mean.
A negative (positive) z-score indicates that the value is below (above) the mean.
Z-scores can be used to calculate the probabilities of a normal random variable using the normal tables in the back of the book.

43. Standard Score (z – score)
The formula for converting any value x to a z-score is .
A z-score measures the number of standard deviations that a value falls from the mean

44. Shifting and Rescaling Data
Shifting data:
Adding (or subtracting) a constant to every data value adds (or subtracts) the same constant to measures of position.
Adding (or subtracting) a constant to each value will increase (or decrease) measures of position: center, percentiles, max or min by the same constant.
Its shape and spread - range, IQR, standard deviation - remain unchanged.

45. Shifting and Rescaling Data
The following histograms show a shift from men’s actual weights to kilograms above recommended weight:

46. Shifting and Rescaling Data
When we multiply (or divide) all the data values by any constant, all measures of position (such as the mean, median, and percentiles) and measures of spread (such as the range, the IQR, and the standard deviation) are multiplied (or divided) by that same constant.

47. Shifting and Rescaling Data
The men’s weight data set measured weights in kilograms. If we want to think about these weights in pounds, we would rescale the data:

48. Examples: Midterm Exam II Practice Sheet

49. Z-Scores and the Standard Normal Distribution
A standard normal distribution has mean and standard deviation
When a random variable has a normal distribution and its values are converted to z-scores by subtracting the mean and dividing by the standard deviation, the z-scores follow the standard normal distribution.

50. Table Z: Standard Normal Probabilities
Table Z enables us to find normal probabilities.
It tabulates the normal cumulative probabilities falling below the point
To use the table:
Find the corresponding z-score.
Look up the closest standardized score (z) in the table.
First column gives z to the first decimal place.
First row gives the second decimal place of z.
The corresponding probability found in the body of the table gives the probability of falling below the z-score.

51. Finding Probabilities Using The Standard Normal Table (Table Z)
The figure shows us how to find the area to the left when we have a z-score of 1.80:

52. Example: Using Table Z
Find the probability that a normal random variable takes a value less than 1.43 standard deviations above ;

53. Example: Using Table Z
Find the probability that a normal random variable assumes a value within 1.43 standard deviations of .
Probability below

54. Example: Using Table Z
Figure 8.7 The Normal Cumulative Probability, Less than z Standard Deviations above the Mean. Table Z lists a cumulative probability of for , so is the probability less than 1.43 standard deviations above the mean of any normal distribution (that is, below ). The complement probability of is the probability above in the right tail.

55. From Percentiles to z - Scores
Sometimes we start with areas and need to find the corresponding z-score or even the original data value.
Example: What z-score represents the first quartile in a Normal model?

56. From Percentiles to z - Scores
Look in Table Z for an area of
The exact area is not there, but is pretty close.
This figure is associated with z = -0.67, so the first quartile is 0.67 standard deviations below the mean.

57. How Can We Find the Value of z for a Certain Cumulative Probability?
To solve some of our problems, we will need to find the value of z that corresponds to a certain normal cumulative probability.
To do so, we use Table A in reverse.
Rather than finding z using the first column (value of z up to one decimal) and the first row (second decimal of z).
Find the probability in the body of the table.
The z-score is given by the corresponding values in the first column and row.

58. How Can We Find the Value of z for a Certain Cumulative Probability?
Example: Find the value of z for a cumulative probability of
Look up the cumulative probability of in the body of Table A.
A cumulative probability of 0.025
corresponds to
Thus, the probability that a normal
random variable falls at least
1.96 standard deviations
below the mean is

59. Are You Normal? Normal Probability Plots
When you actually have your own data, you must check to see whether a Normal model is reasonable.
Looking at a histogram of the data is a good way to check that the underlying distribution is roughly unimodal and symmetric.
A more specialized graphical display that can help you decide whether a Normal model is appropriate is the Normal probability plot.
If the distribution of the data is roughly Normal, the Normal probability plot approximates a diagonal straight line. Deviations from a straight line indicate that the distribution is not Normal.

60. Are You Normal? Normal Probability Plots
Nearly Normal data have a histogram and a Normal probability plot that look somewhat like this example:

61. Are You Normal? Normal Probability Plots
A skewed distribution might have a histogram and Normal probability plot like below. In such cases it is unwise to use the Normal Model.

62. Example: Comparing Test Scores That Use Different Scales
Z-scores can be used to compare observations from different normal distributions.
Picture the Scenario:
There are two primary standardized tests used by college admissions, the SAT and the ACT.
You score 650 on the SAT which has and and 30 on the ACT which has and
How can we compare these scores to tell which score is relatively higher?

63. Using Z-scores to Compare Distributions
Compare z-scores:
SAT:
ACT:
Since your z-score is greater for the ACT, you
performed relatively better on this exam.

64. SUMMARY: Using Z-Scores to Find Normal Probabilities or Random Variable x Values
If we’re given a value x and need to find a probability, convert x to a z-score using , use a table of normal probabilities (or software, or a calculator) to get a cumulative probability and then convert it to the probability of interest
If we’re given a probability and need to find the value of x , convert the probability to the related cumulative probability, find the z-score using a normal table (or software, or a calculator), and then evaluate

65. Examples: Midterm Exam II Practice Sheet

66. Binomial Probability Model
Probabilities When Each Observation Has Two Possible Outcomes

67. The Binomial Distribution: Probabilities for Counts with Binary Data
We use the binomial distribution when each observation is binary: it has one of two possible outcomes.
Examples:
Accept or decline an offer from a bank for a credit card.
Have or do not have health insurance.
Vote yes or no on a referendum.

68. Conditions for the Binomial Distribution
Each of n trials has two possible outcomes: “success” or “failure”.
Each trial has the same probability of success, denoted by p, so the probability of a failure is denoted by
The n trials are independent, That is, the result for one trial does not depend on the results of other trials.
The binomial random variable X is the number of successes in the n trials.

69. Probabilities for a Binomial Distribution
When the number of trials n is large, it’s tedious to write out all the possible outcomes in the sample space. There is a formula you can use to find binomial probabilities for any n.
Denote the probability of success on a trial by p. For n independent trials, the probability of x successes equals:

70. Factorials
Rules for factorials:
For example,

71. Example: Midterm II Exam Practice Sheet

72. Example: An ESP Experiment
John Doe claims to possess extrasensory perception (ESP).
An experiment is conducted:
A person in one room picks one of the integers 1, 2, 3, 4, 5 at random.
In another room, John Doe identifies the number he believes was picked.
Three trials are performed for the experiment.
John Doe got the correct answer twice.

73. Example: An ESP Experiment
If John Doe does not actually have ESP and is actually guessing the number, what is the probability that he’d make a correct guess on two of the three trials?
The three ways John Doe could make two correct
guesses in three trials are: SSF, SFS, and FSS.
Each of these has probability:
The total probability of two correct guesses is .

74. Example: An ESP Experiment
The probability of exactly 2 correct guesses is the binomial probability with n = 3 trials, x = 2 correct guesses and p = 0.2 probability of a correct guess.

75. Warning!!!!!!!!!!!!!!!!!!
Before using the binomial distribution, check that its three conditions apply:
Binary data (success or failure)
The same probability of success for each trial (denoted by p)
Independent trials

76. Example: Midterm Exam II Practice Sheet

77. Mean and Standard Deviation of the Binomial Distribution
Binomial Mean and Standard Deviation:
The binomial probability distribution for n trials with probability p of success on each trial has mean and standard deviation given by:

78. Example: Midterm II Exam Practice Sheet

79. Example: Checking for Racial Profiling
In 2006, the New York City Police Department (NYPD) confronted approximately 500,000 pedestrians for suspected criminal violations.
88.9% were non-white.
Meanwhile, according to the 2006 American Community Survey conducted by the U.S. Census Bureau, of the more than 8 million individuals living in New York City, 44.6% were white.
Are the data presented above evidence of racial profiling in police officers’ decisions to confront particular individuals?

80. Example: Checking for Racial Profiling
Assume:
500,000 confrontations as n = 500,000 trials
P(driver is non-white) is p = 0.554
Calculate the mean and standard deviation of this binomial distribution:

81. Example: Checking for Racial Profiling
Recall: Empirical Rule
When a distribution is bell-shaped, close to 100% of the observations fall within 3 standard deviations of the mean:
If no racial profiling is taking place, we would not be surprised if between about 275,947 and 278,053 of the 500,000 people stopped were non- white. However, 88.9% of all stops, or 500,000(0.889) = 444,500 involved non-whites. This suggests that the number of non-whites stopped is much higher than we would expect if the probability of confronting a pedestrian were the same for each resident, regardless of their race.

82. Extra – Credit Work Follows

83. Section 8.8 Sums, Differences of Discrete RVs
A linear combination of random variables, X, Y, is a combination of the form:
L = aX + bY + …
where a, b, etc. are numbers – positive or negative.
Most common: Sum = X + Y Difference = X – Y

84. Section 8.8 Means of Linear Combination
L = aX + bY + …
The mean of L is:
Mean(L) = a Mean(X) + b Mean(Y) + …
Most common:
Mean( X + Y) = Mean(X) + Mean(Y)
Mean(X – Y) = Mean(X) – Mean(Y)

85. Section 8.8 Variances of Linear Combination
If X, Y, are independent random variables, then
Variance(L) = a2 Variance(X) + b2 Variance(Y) + …
Most common:
Variance( X + Y) = Variance(X) + Variance(Y)
Variance(X – Y) = Variance(X) + Variance(Y)

86. Extra – Credit Exercises