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DefinitionsExperimentAny happening whose result is uncertain.OutcomesPossible results from an experimentSample SpaceSet of all possible outcomesEventSubset of the sample space. One or more outcomes.Equally Likely EventsEvents which have the same chance of occurringProbabilityChance that an event will occur. Theoretically for equally likely events, it is the number of ways an event can occur divided by number of outcomes in the sample space. Empirically, the long term relative frequency.Independent EventsEvents in which the occurrence of one event does not change the probability of the occurrence of the other. One does not affect the other.Dependent EventsEvents that are not independent.Mutually Exclusive EventsEvents that can not happen at the same time. Disjoint events.All Inclusive EventsEvents whose union comprises the totality of the sample space.Complementary EventsTwo mutually exclusive events that are all inclusive.Sample SpacesThe sample space is the set of all the possible outcomes in an experiment and is denoted by a capital letter S. If you were to roll a single die, then S = { 1, 2, 3, 4, 5, 6 }, the set of all possible outcomes. If you were to roll two dice and look at the sum of the two dice, then S = { 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 }. Equally Likely EventsHowever, not all sample spaces are created equally. In fact, that last example is not. There is only one way that a sum of 2 can be rolled, a 1 on the first die and a 1 on the second die. There are four ways that a sum of five can be rolled: 1-4, 2-3, 3-2, 4-1 (don't be confused here, 1-4 is a 1 on the first die and a 4 on the second and is different than a 4 on the first and a 1 on the second. If it helps, pretend that you're rolling one die and a friend is rolling the other). We want our sample spaces to be equally likely if at all possible. Classical / Theoretical ProbabilityIf outcomes are equally likely, then the probability of an event occurring is the number in the event divided by the number in the sample space. P(E) = n(E) / n(S) The probability of rolling a six on a single roll of a die is 1/6 because there is only 1 way to roll a six out of 6 ways it could be rolled. The probability of getting a sum of 5 when rolling two dice is 4/36 = 1/9 because there are 4 ways to get a five and there are 36 ways to roll the dice (Fundamental Counting Principle - 6 ways to roll the first times 6 ways to roll the second). Do not make the mistake of saying that the probability of rolling a sum of 5 is 1/11 because there is one 5 out of a sample space of 11 sums (2 through 12). When the sample spaces are not equally likely, do not divide by the number in the sample space. Properties of Probabilities
Addition RulesWhen you want to find the probability of one event OR another occurring, you add their probabilities together. This can lead to problems however, if they have something in common. The probability of one or both of two events occurring is ... P(A or B) = P(A) + P(B) - P(A and B) Mutually Exclusive EventsMutually Exclusive Events have nothing in common. The intersection of the two events is the empty set. The probability of A and B both occurring is 0 because they can't occur at the same time. If two events are mutually exclusive, then the probability of one or the other occurring is ... P(A or B) = P(A) + P(B) Multiplication RulesWhen you want to find the probability of two events both occurring, then you need to apply the Fundamental Counting Principle. This principle can be extended to probabilities. Independent EventsIndependent Events are events where one occurring doesn't change the probability of the other occurring. When events are independent, the probability of them both occurring is ... P(A and B) = P(A) * P(B) We don't have time to get into probability very deeply. If we did, we would cover conditional probability - the probability of dependent events. Complementary EventsThe root word in complementary is "complete". Complementary events complete, or make whole. Complementary events are mutually exclusive, but when combined make the entire sample space. The symbol for the complement of event A is A'. Some books will put a bar over the set to indicate its complement. Since complementary events are mutually exclusive, we can use the special addition rule to find its probability. Furthermore, complementary events are all inclusive, so they make the sample space when combined, so their probabilities have a sum of 1. The sum of the probabilities of complementary events is 1. P(A) + P(A') = 1 Is how many times an event occurs divided by the total number of trials?The relative frequency of an event is defined as the number of times that the event occurs during experimental trials, divided by the total number of trials conducted. The relative frequency is not a theoretical quantity, but an experimental one.
What type of probability pertains to the number of ways the event can occur favorable outcomes divided by the number of total outcomes?Probability of an event E = p(E) = (number of favorable outcomes of E)/(number of total outcomes in the sample space) This approach is also called theoretical probability. The example of finding the probability of a sum of seven when two dice are tossed is an example of the classical approach.
What compared the number of events that occur to the total number of possible events?Probability is a type of ratio where we compare how many times an outcome can occur compared to all possible outcomes.
Which of the following is the number of ways an event can occur?Summary: The probability of an event is the measure of the chance that the event will occur as a result of an experiment. The probability of an event A is the number of ways event A can occur divided by the total number of possible outcomes.
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What is the number of ways that an event can occur divided by the total number of outcomes?
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