Chapter 5 Continuous Probability Distributions Chapter 5 Chapter
Chapter 5 Continuous Probability Distributions ©
Chapter 5 - Chapter Outcomes After studying the material in this chapter, you should be able to: • Discuss the important properties of the normal probability distribution. • Recognize when the normal distribution might apply in a decision-making process.
Chapter 5 - Chapter Outcomes (continued) After studying the material in this chapter, you should be able to: • Calculate probabilities using the normal distribution table and be able to apply the normal distribution in appropriate business situations. • Recognize situations in which the uniform and exponential distributions apply.
Continuous Probability Distributions A discrete random variable is a variable that can take on a countable number of possible values along a specified interval.
Continuous Probability Distributions A continuous random variable is a variable that can take on any of the possible values between two points.
Examples of Continuous Random variables • Time required to perform a job • Financial ratios • Product weights • Volume of soft drink in a 12 -ounce can • Interest rates • Income levels • Distance between two points
Continuous Probability Distributions The probability distribution of a continuous random variable is represented by a probability density function that defines a curve.
Continuous Probability Distributions (a) Discrete Probability Distribution (b) Probability Density Function P(x) f(x) x x Possible Values of x
Normal Probability Distribution The Normal Distribution is a bell-shaped, continuous distribution with the following properties: 1. It is unimodal 2. It is symmetrical; symmetrical this means 50% of the area under the curve lies left of the center and 50% lies right of center. 3. The mean, median, and mode are equal. 4. It is asymptotic to the x-axis. 5. The amount of variation in the random variable determines the width of the normal distribution.
Normal Probability Distribution NORMAL DISTRIBUTION DENSITY FUNCTION where: x = Any value of the continuous random variable = Population standard deviation e = Base of the natural log = 2. 7183 = Population mean
Normal Probability Distribution (Figure 5 -2) f(x) Probability = 0. 50 Mean Median Mode x
Differences Between Normal Distributions (Figure 5 -3) x (a) x (b) (c) x
Standard Normal Distribution The standard normal distribution is a normal distribution which has a mean = 0. 0 and a standard deviation = 1. 0. The horizontal axis is scaled in standardized z-values that measure the number of standard deviations a point is from the mean. Values above the mean have positive z-values and those below have negative zvalues.
Standard Normal Distribution STANDARDIZED NORMAL Z-VALUE where: x = Any point on the horizontal axis = Standard deviation of the normal distribution = Population mean z = Scaled value (the number of standard deviations a point x is from the mean)
Areas Under the Standard Normal Curve (Using Table 5 -1) 0. 1985 0 0. 52 Example: z = 0. 52 (or -0. 52) P(0 < z <. 52) = 0. 1985 or 19. 85% X
Areas Under the Standard Normal Curve (Table 5 -1)
Standard Normal Example (Figure 5 -6) Probabilities from the Normal Curve for Westex 0. 1915 x=45 50 x 0. 50 z= -. 50 0 z
Standard Normal Example (Figure 5 -7) z z=-1. 25 x=7. 5 From the normal table: P(-1. 25 z 0) = 0. 3944 Then, P(x 7. 5 hours) = 0. 50 - 0. 3944 = 0. 1056
Uniform Probability Distribution The uniform distribution is a probability distribution in which the probability of a value occurring between two points, a and b, is the same as the probability between any other two points, c and d, given that the distribution between a and b is equal to the distance between c and d.
Uniform Probability Distribution CONTINUOUS UNIFORM DISTRIBUTION where: f(x) = Value of the density function at any x value a = Lower limit of the interval from a to b b = Upper limit of the interval from a to b
Uniform Probability Distributions (Figure 5 -16) f(x) for 2 x 5 f(x) . 50 . 25 2 a 5 b for 3 x 8 3 a 8 b
Exponential Probability Distribution The exponential probability distribution is a continuous distribution that is used to measure the time that elapses between two occurrences of an event.
Exponential Probability Distribution EXPONENTIAL DISTRIBUTION A continuous random variable that is exponentially distributed has the probability density function given by: where: e = 2. 71828. . . 1/ = The mean time between events ( >0)
Exponential Distributions (Figure 5 -18) f(x) Lambda = 3. 0 (Mean = 0. 333) Lambda = 2. 0 (Mean = 0. 5) Lambda = 1. 0 (Mean = 1. 0) Lambda = 0. 50 (Mean = 020) Values of x x
Exponential Probability EXPONENTIAL PROBABILITY
Key Terms • Continuous Random Variable • Discrete Random Variable • Exponential Distribution • Normal Distribution • Standard Normal Distribution Standard Normal Table • Uniform Distribution • z-Value
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