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Understandable Statistics
Seventh Edition
By Brase and Brase
Prepared by: Lynn Smith
Gloucester County College
Chapter Six
Normal Distributions
Copyright (C) 2002 Houghton Mifflin Company. All rights reserved .
1
The Normal Distribution
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2
Properties of The Normal
Distribution

The curve is bell-shaped with the
highest point over the mean, .
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3
Properties of The Normal
Distribution

The curve is symmetrical about a
vertical line through .
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4
Properties of The Normal
Distribution

The curve approaches the horizontal
axis but never touches or crosses it.
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5
Properties of The Normal
Distribution
–


The transition points between cupping
upward and downward occur
above  +  and  –  .
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6
The Normal Density Function
( x   )2
P( x) 
2 2
e
 2
This formula generates the density curve which
gives the shape of the normal distribution.
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7
The Empirical Rule
Approximately 68% of the data values lie is
within one standard deviation of the mean.
68%

One standard deviation from the mean.
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8
The Empirical Rule
Approximately 95% of the data values lie within
two standard deviations of the mean.
95%
x
Two standard deviations from the mean.
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9
The Empirical Rule
Almost all (approximately 99.7%) of the data
values will be within three standard deviations of
the mean.
99.7%
x
Three standard deviations from the mean.
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10
Application of the Empirical
Rule
The life of a particular type of light bulb
is normally distributed with a mean of
1100 hours and a standard deviation of
100 hours.
What is the probability that a light bulb of
this type will last between 1000 and 1200
hours?
Approximately 68%
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11
Control Chart
a statistical tool to track data over a
period of equally spaced time
intervals or in some sequential
order
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12
Statistical Control
A random variable is in statistical
control if it can be described by the
same probability distribution when
it is observed at successive points in
time.
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13
To Construct a Control Chart
• Draw a center horizontal line at .
• Draw dashed lines (control limits) at
    and   .
• The values of  and  may be target
values or may be computed from past
data when the process was in control.
• Plot the variable being measured using
time on the horizontal axis.
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14
Control Chart





1
2
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3
4
5
6
7
15
Control Chart





1
2
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3
4
5
6
7
16
Out-Of-Control Warning
Signals
I
One point beyond the 3 level
II
A run of nine consecutive points on
one side of the center line at target 
III
At least two of three consecutive
points beyond the 2 level on the same
side of the center line.
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17
Probability of a False Alarm
Warning Signal
Probability of false
alarm
I Point beyond 3
0.003
II Nine conscecutive
points on same side of

III At least 2/3 points
beyond 2
0.004
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0.004
18
Is the Process in Control?





1
2
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3
4
5
6
7
19
Is the Process in Control?





1 2 3 4 5 6 7 8 9 10 11 12 13
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20
Is the Process in Control?





1
2
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3
4
5
6
7
21
Is the Process in Control?





1
2
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3
4
5
6
7
22
Z Score
• The z value or z score tells the number of
standard deviations the original
measurement is from the mean.
• The z value is in standard units.
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23
Formula for z score
x
z

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24
Calculating z-scores
The amount of time it takes for a pizza
delivery is approximately normally
distributed with a mean of 25 minutes
and a standard deviation of 2 minutes.
Convert 21 minutes to a z score.
x   21  25
z

 2.00

2
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25
Calculating z-scores
Mean delivery time = 25 minutes
Standard deviation = 2 minutes
Convert 29.7 minutes to a z score.
x   29.7  25
z

 2.35

2
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26
Interpreting z-scores
Mean delivery time = 25 minutes
Standard deviation = 2 minutes
Interpret a z score of 1.6.
x  z    1.6( 2 )  25  28 .2
The delivery time is 28.2 minutes.
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27
Standard Normal Distribution:

=0

=1
-1
0
1
Values are converted to z

scores wherexz =

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28
Importance of the Standard
Normal Distribution:
Standard
Normal
Distribution:
Any Normal
Distribution:
0
1
Areas will be equal.

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1
29
Use of the Normal Probability
Table
(Table 5) - Appendix II
Entries give the probability that a
standard normally distributed
random variable will assume a
value to the left of a given negative
z-score.
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30
Use of the Normal Probability
Table
(Table 5a) - Appendix II
Entries give the probability that a
standard normally distributed
random variable will assume a
value to the left of a given positive z
value.
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31
To find the area to the left of
z = 1.34
_____________________________________
z … 0.03
0.04
0.05 ..…
_____________________________________
.
.
1.2 … .8907
.8925
.8944 ….
1.3 … .9082
.9099
.9115 ….
1.4 … .9236
.9251
.9265 ….
.
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32
Patterns for Finding Areas
Under the Standard Normal
Curve
To find the area to the left of a given
negative z :
Use Table 5 (Appendix II) directly.
z
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0
33
Patterns for Finding Areas
Under the Standard Normal
Curve
To find the area to the left of a given
positive z :
Use Table 5 a (Appendix II) directly.
0
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z
34
Patterns for Finding Areas
Under the Standard Normal
Curve
To find the area between z values on either
side of zero:
Subtract area to left of z1 from area to left
of z2 .
z1
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0
z2
35
Patterns for Finding Areas
Under the Standard Normal
Curve
To find the area between z values on the
same side of zero:
Subtract area to left of z1 from area to left
of z2 .
0
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z1
z2
36
Patterns for Finding Areas
Under the Standard Normal
Curve
To find the area to the right of a positive z
value or to the right of a negative z value:
Subtract from 1.0000 the area to the left of the
given z.
Area under
entire curve
= 1.000.
0
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z
37
Use of the Normal Probability
Table
a.
.8925
P(z < 1.24) = ______
b.
.4452
P(0 < z < 1.60) = _______
c.
.4911
P( - 2.37 < z < 0) = ______
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38
Normal Probability
d.
.9974
P( - 3 < z < 3 ) = ________
e.
.9322
P( - 2.34 < z < 1.57 ) = _____
f.
.0774
P( 1.24 < z < 1.88 ) = _______
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39
Normal Probability
g.
.2254
P( - 2.44 < z < - 0.73 ) = _______
h.
.9495
P( z < 1.64 ) = __________
i.
.0084
P( z > 2.39 ) = _________
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40
Normal Probability
j.
.9236
P ( z > - 1.43 ) = __________
k.
.0034
P( z < - 2.71 ) = __________
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41
Application of the Normal
Curve
The amount of time it takes for a pizza delivery is
approximately normally distributed with a mean of 25
minutes and a standard deviation of 2 minutes. If you order
a pizza, find the probability that the delivery time will be:
a.
between 25 and 27 minutes.
.3413
a. ___________
b.
less than 30 minutes.
.9938
b. __________
c.
less than 22.7 minutes.
.1251
c. __________
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42
Inverse Normal Distribution
Finding z scores when probabilities
(areas) are given
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43
Find the indicated z score:
Find the indicated z score:
.8907
0
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z=
1.23
44
Find the indicated z score:
.6331
.3669
z = – 0.34
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45
Find the indicated z score:
.3560
.8560
0
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z=
1.06
46
Find the indicated z score:
.4792
.0208
z = – 2.04
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0
47
Find the indicated z score:
.4900
0
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z=
2.33
48
Find the indicated z score:
.005
z = – 2.575
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0
49
Find the indicated z score:
A
= .005
–z
B
0
z
 2.575 or  2.58
If area A + area B = .01, z = __________
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50
Application of Determining z
Scores
The Verbal SAT test has a mean score of
500 and a standard deviation of 100.
Scores are normally distributed. A major
university determines that it will accept
only students whose Verbal SAT scores
are in the top 4%. What is the minimum
score that a student must earn to be
accepted?
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51
...students whose Verbal SAT
scores are in the top 4%.
Mean = 500, standard deviation = 100
.9600
= .04
z = 1.75
The cut-off score is 1.75 standard deviations
above the mean.
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52
Application of Determining z
Scores
Mean = 500, standard deviation = 100
.9600
= .04
z = 1.75
The cut-off score is 500 + 1.75(100) = 675.
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53
Normal Approximation Of The
Binomial Distribution:
Under certain conditions, a
binomial random variable has a
distribution that is approximately
normal.
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54
Using the normal distribution
to approximate the binomial
distribution
If n, p, and q are such that:
np and nq
are both greater than 5.
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55
Mean and Standard Deviation:
Binomial Distribution
  np and   npq
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56
Experiment: tossing a coin 20
times
Problem: Find the probability of getting
exactly 10 heads.
Distribution of the number of heads appearing should look like:
0
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10
20
57
Using the Binomial
Probability Formula
n=
20
x=
10
P(10) = 0.176197052
p=
0.5
q = 1  p = 0.5
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58
Normal Approximation of the
Binomial Distribution
First calculate the mean
and standard deviation:
 = np = 20 (.5) = 10
  np(1  p ) 
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20(.5)(.5)  5  2.24
59
The Continuity Correction
Continuity Correction: to compute the
probability of getting exactly 10 heads, find
the probability of getting between 9.5
and 10.5 heads.
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60
The Continuity Correction
Continuity Correction is needed because
we are approximating a discrete
probability distribution with a
continuous distribution.
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61
The Continuity Correction
We are using the area under the
curve to approximate the area of the
rectangle.
9.5 - 10.5
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62
Using the Normal Distribution
P(9.5 < x < 10.5 ) = ?
for x = 9.5: z =  0.22
P(z <  0.22 ) = .4129
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63
Using the Normal Distribution
for x = 10.5: z = = 0.22
P( z < .22) = .5871
P(9.5 < x < 10.5 ) .5871
= - .4129 = .1742
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64
Application of Normal
Distribution
If 22% of all patients with high blood pressure
have side effects from a certain medication,
and 100 patients are treated, find the
probability that at least 30 of them will
have side effects.
Using the Binomial Probability Formula we would need
to compute:
P(30) + P(31) + ... + P(100) or 1  P( x < 29)
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65
Using the Normal
Approximation to the
Binomial Distribution
Is it appropriate to use the
normal distribution?
Check: n p =
nq=
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66
Using the Normal
Approximation to the
Binomial Distribution
n p = 22
n q = 78
Both are greater than five.
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67
Find the mean and standard
deviation
 = 100(.22) = 22
and  = 100(.22)(.78) 
17.16  4.14
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68
Applying the Normal
Distribution
To find the probability that at least 30 of
them will have side effects, find P( x  29.5)
Find this area
22
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29.5
69
Applying the Normal
Distribution
The probability that
at least 30 of the
patients will have
side effects is 0.0351.
z = 29.5 – 22 = 1.81
4.14
Find P( z  1.81)
.9649
= .0351
0
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1.81
70
Reminders:
• Use the normal distribution to
approximate the binomial only if both np
and nq are greater than 5.
• Always use the continuity correction
when approximating the binomial
distribution.
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71