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Probability & Statistics for Engineers & Scientists, by Walpole, Myers, Myers & Ye ~ Chapter 8 Notes

Probability & Statistics for Engineers & Scientists, by Walpole, Myers, Myers & Ye ~ Chapter 8 Notes. Class notes for ISE 201 San Jose State University Industrial & Systems Engineering Dept. Steve Kennedy. Populations & Samples.

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Probability & Statistics for Engineers & Scientists, by Walpole, Myers, Myers & Ye ~ Chapter 8 Notes

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  1. Probability & Statistics for Engineers & Scientists, byWalpole, Myers, Myers & Ye ~Chapter 8 Notes Class notes for ISE 201 San Jose State University Industrial & Systems Engineering Dept. Steve Kennedy

  2. Populations & Samples • A population is the set (possibly infinite) of all possible observations. • Each observation is a random variable X having some (often unknown) probability distribution, f (x). • If the population distribution is known, it might be referred to, for example, as a normal population, etc. • A sample is a subset of a population. • Our goal is to make inferences about the population based on an analysis of the sample. • A biased sample, usually obtained by taking convenient, rather than representative observations, will consistently over- or under-estimate some characteristic of the population. • Observations in a random sample are made independently and at random. Here, random variables X1, X2, …, Xn in the sample all have same distribution as the population, X.

  3. Sample Statistics • Any function of the random variables X1, X2, …, Xn making up a random sample is called a statistic. • The most important statistics, as we have seen are the sample mean, sample variance and sample standard deviation:

  4. Sampling Distributions • Starting with an unknown population distribution, we can study the sampling distribution, or distribution of a sample statistic (like Xbar or S) calculated from a sample of size n from that population. • The sample consists of independent and identically distributed observations X1, X2, …, Xn from the population. • Based on the sampling distributions of Xbar and S for samples of size n, we will make inferences about the population mean and variance  and . • We could approximate the sampling distribution of Xbar by taking a large number of random samples of size n and plotting the distribution of the Xbar values.

  5. Sampling Distribution Summary • Normal distribution: Sampling distribution of Xbar when  is known for any population distribution. • Also the sampling distribution for the difference of the means of two different samples. • t-distribution: Sampling distribution of Xbar when  is unknown and S is used. Population must be normal. • Also the sampling distribution for the difference of the means of two different samples when  is unknown. • Chi-square (2) distribution: Sampling distribution of S2. Population must be normal. • F-distribution: The distribution of the ratio of two 2 random variables. Sampling distribution of the ratio of the variances of two different samples. Population must be normal.

  6. Central Limit Theorem • The central limit theorem is the most important theorem in statistics. It states that • If Xbar is the mean of a random sample of size n from a population with an arbitrary distribution with mean  and variance 2, then as n, the sampling distribution of Xbar approaches a normal distribution with mean  and standard deviation /n . • The central limit theorem holds under the following conditions: • For any population distribution if n  30. • For n < 30, if the population distribution is generally shaped like a normal distribution. • For any value of n if the population distribution is normal.

  7. Inferences About the Population Mean • We often want to test hypotheses about the population mean (hypothesis testing will be formalized later). • Example: • Suppose a manufacturing process is designed to produce parts with  = 6 cm in diameter, and suppose  is known to be .15 cm. If a random sample of 80 parts has xbar = 6.046 cm, what is the probability (P-value) that a value this far from the mean could occur by chance if  is truly 6 cm?

  8. Difference Between Two Means • In addition, we can make inferences about the difference between two population means based on the difference between two sample means. • The central limit theorem also holds in this case. • If independent samples of size n1 and n2 are drawn at random from two populations, discrete or continuous, with means 1 and 2, and variances 12 and 22, then as n gets large, the sampling distribution of Xbar1 - Xbar2 approaches a normal distribution with

  9. Difference of Two Means Example • Example: • Suppose we record the drying time in hours of 20 samples each of two types of paint, type A and type B. Suppose we know that the population standard deviations are both equal to 1/2 hour. Assuming that the population means are equal, what is the probability that the difference in the sample means is greater than 1/2 hour? • P(z > 3.16) = .0008. Very unlikely to happen by chance.

  10. t-Distribution (when  is Unknown) • The problem with the central limit theorem is that it assumes that  is known. • Generally, if  is being estimated from the sample,  must be estimated from the sample as well. • The t-distribution can be used if  is unknown, but it requires that the original population must be normally distributed. • Let X1, X2, ..., Xn be independent, normally distributed random variables with mean  and standard deviation . Then the random variable T below has a t-distribution with  = n - 1 degrees of freedom: • The t-distribution is like the normal, but with greater spread since both  and  have fluctuations due to sampling.

  11. Using the t-Distribution • Observations on the t-Distribution: • The t-statistic is like the normal, but using S rather than . • Table value depends on the sample size (degrees of freedom). • The t-distribution is symmetric with  = 0, but 2 > 1. As would be expected, 2 is largest for small n. • Approaches the normal distribution (2 = 1) as n gets large. • For a given probability , table shows the value of t that has P() to the right of it. • The t-distribution can also be used for hypotheses concerning the difference of two means where 1 and 2 are unknown, as long as the two populations are normally distributed. • Usually if n  30, S is a good enough estimator of , and the normal distribution is typically used instead.

  12. Sampling Distribution of S2 • If S2 is the variance of a random sample of size n taken from a normal population with known variance 2, then the statistic 2 below has a chi-squared distribution with  = n-1 degrees of freedom: • The 2 table is the reverse of the normal table. • It shows the 2 value that has probability  to the right of it. • Note that the 2 distribution is not symmetric. • Degrees of freedom: • As before, you can think of degrees of freedom as the number of independent pieces of information. We use  = n-1, since one degree of freedom is subtracted due to the fact that the sample mean is used to estimate  when calculating S2. • If  is known, use n degrees of freedom.

  13. F-Distribution Comparing Sample Variances • The F statistic is the ratio of two 2 random variables, each divided by its number of degrees of freedom. • If S12 and S22 are the variances of samples of size n1 and n2 taken from normal populations with variances 12 and 22, then has an F-distribution with 1 = n1 - 1 and 2 = n2 - 1 degrees of freedom. • For the F-distribution table • Note that since the ratio is inverted, 1 and 2 are reversed.

  14. F-Distribution Usage • The F-distribution is used in two-sample situations to draw inferences about the population variances. • In an area of statistics called analysis of variance, sources of variability are considered, for example: • Variability within each of the two samples. • Variability between the two samples (variability between the means). • The overall question is whether the variability within the samples is large enough that the variability between the means is not significant.

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