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2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-1 Continuous iteration between model and physical system.

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Presentation on theme: "2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-1 Continuous iteration between model and physical system."— Presentation transcript:

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3 2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-1 Continuous iteration between model and physical system.

4 2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-2 Noise variables affect the transformation of inputs to outputs.

5 2-1 Sample Spaces and Events 2-1.1 Random Experiments Definition

6 2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-3 A closer examination of the system identifies deviations from the model.

7 2-1 Sample Spaces and Events 2-1.1 Random Experiments Figure 2-4 Variation causes disruptions in the system.

8 2-1 Sample Spaces and Events 2-1.2 Sample Spaces Definition

9 2-1 Sample Spaces and Events 2-1.2 Sample Spaces Example 2-1

10 2-1 Sample Spaces and Events Example 2-1 (continued)

11 2-1 Sample Spaces and Events Example 2-2

12 2-1 Sample Spaces and Events Example 2-2 (continued)

13 2-1 Sample Spaces and Events Tree Diagrams Sample spaces can also be described graphically with tree diagrams. –When a sample space can be constructed in several steps or stages, we can represent each of the n 1 ways of completing the first step as a branch of a tree. –Each of the ways of completing the second step can be represented as n 2 branches starting from the ends of the original branches, and so forth.

14 2-1 Sample Spaces and Events Figure 2-5 Tree diagram for three messages.

15 2-1 Sample Spaces and Events Example 2-3

16 2-1 Sample Spaces and Events 2-1.3 Events Definition

17 2-1 Sample Spaces and Events 2-1.3 Events Basic Set Operations

18 2-1 Sample Spaces and Events 2-1.3 Events Example 2-6

19 2-1 Sample Spaces and Events Definition

20 2-1 Sample Spaces and Events Venn Diagrams Figure 2-8 Venn diagrams.

21 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Multiplication Rule

22 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations

23 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations : Example 2-10

24 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations of Subsets

25 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations of Subsets: Example 2-11

26 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations of Similar Objects

27 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Permutations of Similar Objects: Example 2-12

28 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Combinations

29 2-1 Sample Spaces and Events 2-1.4 Counting Techniques Combinations: Example 2-13

30 2-2 Interpretations of Probability 2-2.1 Introduction Probability Used to quantify likelihood or chance Used to represent risk or uncertainty in engineering applications Can be interpreted as our degree of belief or relative frequency

31 2-2 Interpretations of Probability 2-2.1 Introduction Figure 2-10 Relative frequency of corrupted pulses sent over a communications channel.

32 2-2 Interpretations of Probability Equally Likely Outcomes

33 2-2 Interpretations of Probability Example 2-15

34 2-2 Interpretations of Probability Figure 2-11 Probability of the event E is the sum of the probabilities of the outcomes in E

35 2-2 Interpretations of Probability Definition

36 2-2 Interpretations of Probability Example 2-16

37 2-2 Interpretations of Probability 2-2.2 Axioms of Probability

38 2-3 Addition Rules Probability of a Union

39 2-3 Addition Rules Mutually Exclusive Events

40 2-3 Addition Rules Three Events

41 2-3 Addition Rules

42 Figure 2-12 Venn diagram of four mutually exclusive events

43 2-3 Addition Rules Example 2-21

44 2-4 Conditional Probability To introduce conditional probability, consider an example involving manufactured parts. Let D denote the event that a part is defective and let F denote the event that a part has a surface flaw. Then, we denote the probability of D given, or assuming, that a part has a surface flaw as P(D|F). This notation is read as the conditional probability of D given F, and it is interpreted as the probability that a part is defective, given that the part has a surface flaw.

45 2-4 Conditional Probability Figure 2-13 Conditional probabilities for parts with surface flaws

46 2-4 Conditional Probability Definition

47 2-5 Multiplication and Total Probability Rules 2-5.1 Multiplication Rule

48 2-5 Multiplication and Total Probability Rules Example 2-26

49 2-5 Multiplication and Total Probability Rules 2-5.2 Total Probability Rule Figure 2-15 Partitioning an event into two mutually exclusive subsets. Figure 2-16 Partitioning an event into several mutually exclusive subsets.

50 2-5 Multiplication and Total Probability Rules 2-5.2 Total Probability Rule (two events)

51 2-5 Multiplication and Total Probability Rules Example 2-27

52 2-5 Multiplication and Total Probability Rules Total Probability Rule (multiple events)

53 2-6 Independence Definition (two events)

54 2-6 Independence Definition (multiple events)

55 Example 2-34

56 2-7 Bayes’ Theorem Definition

57 2-7 Bayes’ Theorem Bayes’ Theorem

58 Example 2-37

59 2-8 Random Variables Definition

60 2-8 Random Variables Definition

61 2-8 Random Variables Examples of Random Variables

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