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Chapter 4 Continuous Random Variables Continuous Probability Distributions Continuous Probability Distribution – areas under curve correspond to probabilities for x Area A corresponds to the probability that x lies between a and b Do you see the similarity in shape between the continuous and discrete probability distributions? The Uniform Distribution Uniform Probability Distribution – distribution resulting when a continuous random variable is evenly distributed over a particular interval Probability Distribution for a Uniform Random Variable x 1 cxd Probability density function: f x d c cd d c Mean: Standard Deviation: 2 12 Pa x b b a /d c, c a b d The Normal Distribution A normal random variable has a probability distribution called a normal distribution The Normal Distribution Bell-shaped curve Symmetrical about its mean μ Spread determined by the value of it’s standard deviation σ The Normal Distribution The mean and standard deviation affect the flatness and center of the curve, but not the basic shape The Normal Distribution The function that generates a normal curve is of the form 1 1 2 x 2 f x e 2 where = Mean of the normal random variable x = Standard deviation = 3.1416… e = 2.71828… P(x<a) is obtained from a table of normal probabilities The Normal Distribution Probabilities associated with values or ranges of a random variable correspond to areas under the normal curve Calculating probabilities can be simplified by working with a Standard Normal Distribution A Standard Normal Distribution is a Normal distribution with =0 and =1 The standard normal random variable is denoted by the symbol z The Normal Distribution Table for Standard Normal Distribution contains probability for the area between 0 and z Partial table below shows components of table Value of z a combination of column and row Probability associated with a particular z value, in this case z=.13, p(0<z<.13) = .0517 Z .00 .01 .02 .03 .04 .05 .06 .07 .08 .09 .0 .1 .2 .3 .0000 .0398 .0793 .1179 .0040 .0438 .0832 .1217 .0080 .0478 .0871 .1255 .0120 .0517 .0910 .1293 .0160 .0557 .0948 .1331 .0199 .0596 .0987 .1368 .0239 .0636 .1026 .1406 .0279 .0675 .1064 .1443 .0319 .0714 .1103 .1480 .0359 .0753 .1141 .1517 The Normal Distribution What is P(-1.33 < z < 1.33)? Table gives us area A1 Symmetry about the mean tell us that A2 = A1 P(-1.33 < z < 1.33) = P(-1.33 < z < 0) +P(0 < z < 1.33)= A2 + A1 = .4082 + .4082 = .8164 The Normal Distribution What is P(z > 1.64)? Table gives us area A2 Symmetry about the mean tell us that A2 + A1 = .5 P(z > 1.64) = A1 = .5 – A2=.5 - .4495 = .0505 The Normal Distribution What is P(z < .67)? Table gives us area A1 Symmetry about the mean tell us that A2 = .5 P(z < .67) = A1 + A2 = .2486 + .5 = .7486 The Normal Distribution What is P(|z| > 1.96)? Table gives us area .5 - A2 =.4750, so A2 = .0250 Symmetry about the mean tell us that A2 = A1 P(|z| > 1.96) = A1 + A2 = .0250 + .0250 =.05 The Normal Distribution What if values of interest were not normalized? We want to know P (8<x<12), with μ=10 and σ=1.5 Convert to standard normal using x z P(8<x<12) = P(-1.33<z<1.33) = 2(.4082) = .8164 The Normal Distribution Steps for Finding a Probability Corresponding to a Normal Random Variable • Sketch the distribution, locate mean, shade area of interest x • Convert to standard z values using z • Add z values to the sketch • Use tables to calculate probabilities, making use of symmetry property where necessary The Normal Distribution Making an Inference How likely is an observation in area A, given an assumed normal distribution with mean of 27 and standard deviation of 3? z value for x=20 is -2.33 P(x<20) = P(z<-2.33) = .5 - .4901 = .0099 You could reasonably conclude that this is a rare event The Normal Distribution You can also use the table in reverse to find a z-value that corresponds to a particular probability What is the value of z that will be exceeded only 10% of the time? Look in the body of the table for the value closest to .4, and read the corresponding z value z = 1.28 The Normal Distribution Which values of z enclose the middle 95% of the standard normal z values? Using the symmetry property, z0 must correspond with a probability of .475 From the table, we find that z0 and –z0 are 1.96 and -1.96 respectively. The Normal Distribution Given a normally distributed variable x with mean 100,000 and standard deviation of 10,000, what value of x identifies the top 10% of the distribution? x0 x0 100,000 Px x0 P z .90 P z 10,000 The z value corresponding with .40 is 1.28. Solving for x0 x0 = 100,000 +1.28(10,000) = 100,000 +12,800 = 112,800 Descriptive Methods for Assessing Normality • Evaluate the shape from a histogram or stemand-leaf display • Compute intervals about mean x s, x 2s, x 3s and corresponding percentages • Compute IQR and divide by standard deviation. Result is roughly 1.3 if normal • Use statistical package to evaluate a normal probability plot for the data Approximating a Binomial Distribution with a Normal Distribution You can use a Normal Distribution as an approximation of a Binomial Distribution for large values of n Often needed given limitation of binomial tables Need to add a correction for continuity, because of the discrete nature of the binomial distribution Correction is to add .5 to x when converting to standard z values Rule of thumb: interval +3 should be within range of binomial random variable (0-n) for normal distribution to be adequate approximation Approximating a Binomial Distribution with a Normal Distribution Steps • Determine n and p for the binomial distribution • Calculate the interval 3 np 3 npq • Express binomial probability in the form P(x<a) or P(x<b)–P(x<a) • Calculate z value for each a, applying continuity correction • Sketch normal distribution, locate a’s and use table to solve