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RES 341 RESEARCH AND EVALUATION

RES 341 RESEARCH AND EVALUATION. WORKSHOP 4 By Dr. Serhat Eren University OF PHOENIX Spring 2002. CHAPTER VII: PROBABILITY 7.1 CHAPTER OBJECTIVES. Basic Probability Rules Random Variables and Probability Distributions The Binomial Probability Distribution

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RES 341 RESEARCH AND EVALUATION

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  1. RES 341RESEARCH AND EVALUATION WORKSHOP 4 By Dr. Serhat Eren University OF PHOENIX Spring 2002

  2. CHAPTER VII: PROBABILITY 7.1 CHAPTER OBJECTIVES • Basic Probability Rules • Random Variables and Probability Distributions • The Binomial Probability Distribution • The Normal Probability Distribution

  3. 7.2 BASIC RULES OF PROBABILITY • Probability is a measure of how likely it is that something will occur. • An experiment is any action whose outcomes are recordable data. • The sample space, S, is the set of all possible outcomes of an experiment.

  4. 7.2 BASIC RULES OF PROBABILITY • As a very simple experiment, consider rolling a single, six-sided die and recording the number of spots on the top facing side. • You know that there are six possible outcomes of the experiment, so the sample space is S = {1, 2, 3, 4, 5, 6}

  5. 7.2 BASIC RULES OF PROBABILITY 7.2.1 Probability of an Event • An event, A, is an outcome or a set of outcomes that are of interest to the experimenter. • The likelihood that the event A will occur is called the probability of A and is written P(A). • The probability of an eventA, P(A), is a measure of the likelihood that an event A will occur.

  6. 7.2 BASIC RULES OF PROBABILITY • When each of the outcomes in a sample space is equally likely, then the probability of A can be calculated using the following formula: • Where nAis the number of outcomes that correspond to the event, A, and N is the total number of outcomes in the sample space, S.

  7. 7.2 BASIC RULES OF PROBABILITY • There are some facts about probabilities that must be true: • 0P(A)1. This says that the probability of an event must be a number between 0 and 1 inclusive. • P(S)=1. This says that the sum of the probabilities for the entire sample space must be equal to 1, or that essentially. • If an event A MUST happen, then P(A)=1, and if the event cannot happen, then P(A)=0.

  8. 7.2 BASIC RULES OF PROBABILITY • The complement of an event A, denoted A', is the set of all outcomes in the sample space, S, that do not correspond to the event A. • Since the event A is a set of outcomes in S and the complement of the event A' is the set of all outcomes in S that do NOT correspond to A, we can see that P(A) + P(A') = 1

  9. 7.2 BASIC RULES OF PROBABILITY 7.2.2 Combinations of Events-OR and AND • The event AORB describes the event that either A happens or B happens or they both happen. • The event AANDB is the event that A and B both occur. • Two events, A and B, are said to be mutually exclusiveif they have no outcomes in common.

  10. 7.2 BASIC RULES OF PROBABILITY • When two events are mutually exclusive, then the probability that A occurs orB occurs, P(AORB), is the sum of the individual probabilities. P(AORB) = P(A) + P(B) • The simple addition rule easily extends to any number of mutually exclusive events. For example, if A, B, C, and D are four mutually exclusive events, then P(AORBORCORD) = P(A) + P(B) + P(C) + P(D)

  11. 7.2 BASIC RULES OF PROBABILITY • How can we adjust the simple addition rule of probability to work in situations when the events are NOT mutually exclusive? • The problem occurs when an outcome is included in both events in AANDB. The answer obtained by adding the individual probabilities was too large because the probability that both AANDB occur, P(AANDB), is included in both individual probabilities.

  12. 7.2 BASIC RULES OF PROBABILITY • If we consider this we can come up with a general addition rule for probability that considers the probability of AORB when the events are not mutually exclusive: P(AORB) = P(A) + P(B) - P(AANDB)

  13. 7.2 BASIC RULES OF PROBABILITY • When data are collected on two related variables, they are organized by using a cross-classification table or contingency table. • A contingency tableis a table whose possible values of one variable and whose columns represent possible values for a second variable. The entries in the table are the number of times that each pair of values occurs.

  14. 7.2 BASIC RULES OF PROBABILITY 7.2.3 Probabilities as Relative Frequencies • If the data are a good representation of the population, then we can also use the relative frequencies as estimates of the true probabilities for the population. Probabilities calculated in this way are often called empirical probabilities. • An empirical probability is one that is calculated from sample data and is an estimate for the true probability.

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