Applied Statistics and Probability for Engineers

110 CHAPTER 4 CONTINUOUS RANDOM VARIABLES AND PROBABILITY DISTRIBUTIONS

Figure 4-10 Normal probability density functions for

selected values of the parameters and  ^2.

A random variable Xwith probability density function

(4-8)

is a normal random variablewith parameters , where and 0.

Also,

(4-9)

and the notation is used to denote the distribution. The mean and variance

of Xare shown to equal and ^2 ,respectively, at the end of this Section 5-6.

N 1 , ^22

E 1 X 2  and V 1 X 2 ^2

,

f 1 x 2 

1

12   

e

 1 x 22

2 ^2 x

Definition

 = 5 
 = 15 x

σ^2 = 1

σ^2 = 4

f (x) σ (^2) = 1
Random variables with different means and variances can be modeled by normal proba-
bility density functions with appropriate choices of the center and width of the curve. The
value of determines the center of the probability density function and the value of
determines the width. Figure 4-10 illustrates several normal probability density
functions with selected values of and ^2. Each has the characteristic symmetric bell-shaped
curve, but the centers and dispersions differ. The following definition provides the formula for
normal probability density functions.
V 1 X 2 ^2
E 1 X 2 
EXAMPLE 4-10 Assume that the current measurements in a strip of wire follow a normal distribution with a
mean of 10 milliamperes and a variance of 4 (milliamperes)^2. What is the probability that a
measurement exceeds 13 milliamperes?
Let Xdenote the current in milliamperes. The requested probability can be represented as
This probability is shown as the shaded area under the normal probability density
function in Fig. 4-11. Unfortunately, there is no closed-form expression for the integral of a
normal probability density function, and probabilities based on the normal distribution are
typically found numerically or from a table (that we will later introduce).
Some useful results concerning a normal distribution are summarized below and in
Fig. 4-12. For any normal random variable,
Also, from the symmetry of Because f(x) is positive for
all x, this model assigns some probability to each interval of the real line. However, the
f 1 x 2 , P 1 X 2 P 1 X 2 0.5.
P 1  3 X
3  2 0.9973
P 1  2 X
2  2 0.9545
P 1 X
 2 0.6827
P 1 X 132.
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