Section 6.2 ~ Basics of Probability

1. Section 6.2 ~ Basics of Probability Introduction to Probability and Statistics Ms. Young

2. Objective Sec. 6.2 • After this section you will know how to find probabilities using theoretical and relative frequency methods and understand how to construct basic probability distributions.

3. Sec. 6.2 Basics of Probability • Outcomes – the most basic possible results of observations or experiments • Ex. ~ There are four outcomes of tossing two coins, HH, HT, TH, or TT • Event – a collection of one or more outcomes that share a property of interest • Ex. ~ Suppose you are only interested in the number of heads that appear when you toss two coins. There would be three events, 0 heads (TT), 1 head (HT or TH), or two heads (HH)

4. Sec. 6.2 Basics of Probability Cont’d… • To express a probability, you use numbers between 0 and 1 inclusive • A probability of 0 would represent an event that is impossible • Ex. ~ Meeting a married bachelor • A probability of 1 would represent an event that is certain to occur • Ex. ~ Death and taxes! • The probability of an event is written as P(event) • Ex. ~ The probability of landing a head on a coin toss would be written as P(H) = .5 • The scale to the right shows common expressions used to represent probabilities based on their level in comparison to 0 and 1 • Ex. ~ A probability of .95 indicates that an event is very likely to occur (95 out of 100 times) • Ex. ~ A probability of .30 indicates that an event is unlikely to occur (30 out of 100 times) • Ex. ~ A probability of .01 describes an event that is very unlikely to occur (1 out of 100 times)

5. Sec. 6.2 Theoretical Probabilities • Theoretical probabilities are probabilities that deal with equally likely outcomes (i.e., tossing a fair coin, rolling a fair die, spinning a roulette wheel, etc.) • Calculating theoretical probabilities: • Step 1: Count the total number of possible outcomes • Step 2: Among all the possible outcomes, count the number of ways the event of interest, A, can occur • Step 3: Determine the probability, P(A), from

6. Sec. 6.2 Example 1 • Suppose you select a person at random from a large group. What is the probability that the person has a birthday in July? Assume that there are 365 days in a year. • Since all birthdays are equally likely, we can use the 3 step process for calculating theoretical probabilities: • Step 1: Each possible birthday represents an outcome, so there are 365 possible outcomes • Step 2: July has 31 days, so 31 of the 365 possible outcomes represent the event of a July birthday • Step 3: The probability that a randomly selected person has a birthday in July is

7. Sec. 6.2 Theoretical Probabilities Cont’d… • Counting Outcomes – the total number of outcomes can be found by raising the individual outcome to the number of processes • Ex. ~ What is the total number of outcomes of tossing two coins? • Each coin has 2 outcomes (H or T), and there are 2 coins (2 tosses or processes), so there are 4 possible outcomes (22 = 4) when tossing two coins • Ex. ~ What is the total number of outcomes of tossing three coins? • Each coin has 2 outcomes (H or T), and there are 3 coins (3 tosses or processes), so there are 8 possible outcomes (23 = 8) when tossing three coins

8. Sec. 6.2 Example 2 How many outcomes are there if you roll a fair die and toss a fair coin? The first process, rolling a fair die, has six possible outcomes, 1, 2, 3, 4, 5, or 6, and the second process, tossing a fair coin, has two possible outcomes (H or T). The total number of outcomes would be 12 ( 61× 21). What is the probability of rolling two 1’s (snake eyes) when two fair dice are rolled? Rolling a single die has 6 equally likely outcomes, so rolling two dice has a total of 36 outcomes (62 = 36). Of the 36 outcomes, the event of interest (two 1’s) can only occur one way, so the probability of rolling two 1’s is

9. Sec. 6.2 Example 3 What is the probability that in a randomly selected family with three children, the oldest child is a boy, the second child is a girl, and the youngest child is a girl? Assume that having boys and girls is equally likely. There are two possible outcomes for each birth: boy or girl For a family with three children, there would be 8 possible outcomes (23 = 8) BBB, BBG, BGG, GBB, GBG, GGB, GGG The probability of the birth order being BGG is

10. Sec. 6.2 Relative Frequency Probabilities • Another method to determine probabilities is to approximate the probability of an event, A, occurring. This is known as the relative frequency (or empirical) method. • Ex. ~ If we observe that it rains an average of 100 days per year, we can estimate the probability of it raining on a randomly selected day to be approximately .274 (100/365) • Here is the general rule for this method: • Step 1: Repeat or observe a process many times and count the number of times the event of interest, A, occurs. • Step 2: Estimate P(A) by

11. Sec. 6.2 Example 4 Geological records indicate that a river has crested above a particular high flood level four times in the past 2,000 years. What is the relative frequency probability that the river will crest above the high flood level next year? Because a flood of this magnitude occurs on average once every 500 years, it is called a “500-year flood.” The probability of having a flood of this magnitude in any given year is 1/500, or 0.002.

12. Sec. 6.2 Subjective Probabilities & Summary of Different Methods of Finding Probabilities • A third method for determining probabilities is to estimate a subjective probability using experience or intuition • Ex. ~You could make a subjective estimate of the probability that a friend will be married in the next year or the probability that getting a good grade in statistics will help you get the job that you want • Three approaches to Finding Probability • Theoretical probability – when all outcomes are equally likely, divide the number of ways an event can occur by the total number of outcomes • Relative frequency probability – based on observations or experiments. Divide the number of times the event occurred by the total number of observations • Subjective probability – estimating based on experience or intuition

13. Sec. 6.2 Example 5 Identify the method that resulted in the following statements. a. The chance that you will get married in the next year is zero. Subjective because it’s based on a feeling b. Based on government data, the chance of dying in an automobile accident is 1 in 7,000 (per year). Relative frequency probability because it’s based on observations on passed automobile accidents c. The chance of rolling a 7 with a twelve-sided die is 1/12. Theoretical probability because it is based on assuming that a fair twelve sided die is equally likely to land on any of its twelve sides.

14. Sec. 6.2 Probability of an Event Not Occurring • Sometimes you might be interested in finding the probability that a particular event or outcome does not occur • Ex. ~ The probability of a wrong answer on a multiple choice question with five possible answers • The probability of answering it correctly would be .2 (1/5), so the probability of not answering it correctly would be .8 (4/5) • The complement of an event, A, expressed as , consists of all outcomes in which A does not occur. • The sum of the probabilities of A and must be 1, so the probability of can be given by

15. Sec. 6.2 Example 6 In a grocery store the scanning system was successful 384 out of 419 times. What is the probability that the scanner will not work?

16. Sec. 6.2 Probability Distributions • A probability distribution is a visual display of the probabilities of certain events occurring in the form of a table or a histogram • Ex. ~ Suppose you toss two coins simultaneously. Because each coin can land one of two ways (H or T), there are 4 possible outcomes (HH, TT, HT, & TH). The following table represents the outcomes and probabilities: • Out of the 4 outcomes, there are 3 events, 2 heads (HH), 1 head (HT or TH), and 0 heads (TT). These probabilities result in a probability distribution which can represented as a table or a histogram:

17. Sec. 6.2 Probability Distributions • Steps to making a probability distribution: • Step 1: List all possible outcomes • Step 2: Identify outcomes that represent the same event. Find the probability of each event. • Step 3: Make a table or a histogram in which one column (or x-axis) represents the events and the other column (or y-axis) represents the probability • Example 7: • Make a probability distribution table for the number of heads that occur when three coins are tossed simultaneously. • Step 1: List all possible outcomes • Since there are 3 coins, there are a total of 8 outcomes (23 = 8): HHH, HHT, HTH, HTT, THH, THT, TTH, and TTT (refer to p.241 to see how these outcomes were constructed) • Step 2: Identify outcomes that represent the same event. Find the probability of each. • Since we are interested in the number of heads that occur, there would be 4 events, 0 heads (1/8 = .125), 1 head (3/8 = .375), 2 heads (3/8 = .375), or 3 heads (1/8 = .125)

18. Sec. 6.2 Probability Distributions • Example 7 Cont’d: • Make a probability distribution table for the number of heads that occur when three coins are tossed simultaneously. • Step 3: Make a table