1. Copyright © Cengage Learning. All rights reserved. 6 Normal Probability Distributions

2. Copyright © Cengage Learning. All rights reserved. Notation 6.4

3. 3 Notation The z-score is used throughout statistics in a variety of ways; however, the relationship between the numerical value of z and the area under the standard NORMAL Distribution Curve does not change. Since z is used with great frequency, we want a convenient notation to identify the necessary information. The convention that we will use as an “algebraic name” for a specific z-score is z (  ), where  represents the “area to the right” of the z being named.

4. 4 Visual Interpretation of z (  )

5. 5 Figures 6.6 and 6.7 are both visual interpretations of z (  ). Area Associated with z(0.05)Area Associated with z(0.90) Figure 6.6Figure 6.7

6. 6 Figure 6.6 depicts z(0.05) (read “z of 0.05”), which is the algebraic name for z, such that the area to the right and under the standard normal curve is exactly 0.05. In a similar fashion, Figure 6.7 shows z(0.90) (read “z of 0.90”), which is the value of z, such that 0.90 of the area lies to its right. Visual Interpretation of z (  )

7. 7 Determining Corresponding z Values for z (  )

8. 8 Determining Corresponding z Values for z (  ) Visual representations like those in Figures 6.6 and 6.7 also have corresponding numerical values. Now let’s find the numerical values of z(0.05), z(0.90), and z(0.95). To find the numerical value of z(0.05), we must convert the area information in the notation into information that we can use with Table 3 in Appendix B. Area Associated with z(0.05)Area Associated with z(0.90) Figure 6.6Figure 6.7

9. 9 By subtracting 0.05 from 1, we get 0.95, the area to the left of the z(0.05), which you can see in Figure 6.8. Find the Value of z(0.05) Figure 6.8 Determining Corresponding z Values for z (  )

10. 10 When we look in Table 3, we look for an area as close as possible to 0.9500. We use the z that corresponds to the area closest in value. When the value happens to be exactly halfway between the table entries as above, always use the larger value of z. Therefore, z(0.05) = 1.65. Determining Corresponding z Values for z (  )

11. 11 To find the numerical value of z (0.90), we need to subtract the 0.90 area from 1, which results in an area of 0.10 to the left of z (0.90). The 0.1000 area is the area we can use with Table 3 in Appendix B; as shown in the diagram below. Determining Corresponding z Values for z (  )

12. 12 The closest values in Table 3 are 0.1003 and 0.0985, with 0.1003 being closer to 0.1000. Therefore, z (0.90) is related to –1.28. Since z (0.90) is below the mean, it makes sense that z (0.90) = –1.28. Determining Corresponding z Values for z (  )

13. 13 Because of the symmetrical nature of the normal distribution, z (  ) and z (1 –  ) are closely related, with the only difference being that one is positive and the other is negative. We already found the value of z(0.05) = 1.65. Now let’s find z (0.95). z (0.95) is located on the left-hand side of the normal distribution since the area to the right is 0.95. Determining Corresponding z Values for z (  )

14. 14 The area in the tail to the left then contains the other 0.05, as shown in Figure 6.9. Using Table 3, z (0.95) = –1.65. Area Associated with z(0.95) Figure 6.9 Determining Corresponding z Values for z (  )

15. 15 Because of the symmetrical nature of the normal distribution, z (0.95) = –1.65 and z (0.05) = 1.65 differ only in sign and the side of the distribution to which they belong. Thus, z (0.95) = –z (0.05) = –1.65. In many situations, it will be more convenient to refer to the area of the tail than to either the cumulative area or the area to the right, so we can use this difference as an alternative algebraic name for the z-values bounding a left-side tail situation. In general, when 1 –  is larger than 0.5000, the notation convention we will use is z(1 –  ) = –z (  ). Determining Corresponding z Values for z (  )

16. 16 The z (  ) notation is used regularly in connection with inferential situations involving the area of a tail (extreme ends of a distribution curve—either left or right) region. In later chapters this notation will be used on a regular basis. The values of z that will be used regularly come from one of the following situations: (1) the z-score such that there is a specified area in one tail of the normal distribution, or (2) the z-scores that bound a specified middle proportion of the normal distribution. Determining Corresponding z Values for z (  )

17. 17 When the middle proportion of a normal distribution is specified, we can also use the “area to the right” notation to identify the specific z-score involved. Determining Corresponding z Values for z (  )

18. 18 Table 4 and Commonly Used z Values

19. 19 Table 4 and Commonly Used z Values We already solved two commonly used one-tail situations; z(0.05) = 1.65 is located so that 0.05 of the area under the normal distribution curve is in the tail to the right and z(0.90) = –1.28 is located so that 0.10 of the area under the normal distribution curve is in the tail to the left. Table 4, Critical Values of Standard Normal Distribution, was designed to provide only the most commonly used values of z when the area (s) of the tail regions are given. Part A, One-Tailed Situations, is used when the area of a tail is given. In order to examine this, let’s find the values of z(0.05) and z(0.95) using Table 4.

20. 20 Table 4 and Commonly Used z Values Table 4A, One-Tailed Situations shows us: z(0.05) = 1.65, and since the standard normal distribution is symmetrical, the value of z(0.95) = –z(0.05) = –1.65. Table 4A

21. 21 Determining z-Scores for Bounded Areas

22. 22 Determining z-Scores for Bounded Areas z-scores can also be determined for bounded areas of a normal distribution. For example, we can find the z-scores that bound the middle 0.95 of the normal distribution. Given 0.95 as the area in the middle (see Figure 6.10), the two tails must contain a total of 0.05. Area Associated with Middle 0.95 Figure 6.10

23. 23 Determining z-Scores for Bounded Areas Therefore, each tail contains of 0.05, or 0.025, as shown in Figure 6.11. Finding z-Scores for Middle 0.95 Figure 6.11

24. 24 Determining z-Scores for Bounded Areas The right tail value, z (0.025), is found using Table 4, Part A, One-Tailed Situations, as shown previously. z(0.025) = 1.96, and since the standard normal distribution is symmetrical, the value of z(0.975) = –z(0.025) = –1.96.

25. 25 Determining z-Scores for Bounded Areas Using Two Tails You can use two tails to find the area as well. Given 0.95 as the area in the middle (Figure 6.11), the two tails must contain a total of 0.05. Finding z-Scores for Middle 0.95 Figure 6.11

26. 26 Determining z-Scores for Bounded Areas Table 4, Part B, Two-Tailed Situations, can be used when the combined area of both tails (or the area in the center) is given. Locate the column that corresponds to  = 0.05 or (1 –  ) = 0.95.

27. 27 Determining z-Scores for Bounded Areas From Table 4B we find z(0.05/2) = z(0.025) = 1.96. Using the symmetry property of the distribution, we find z(0.975) = –z(0.025) = –1.96. Therefore, the middle 0.95 of the normal distribution is bounded by –1.96 and 1.96.