1 / 22

BCOR 1020 Business Statistics

BCOR 1020 Business Statistics. Lecture 18 – March 20, 2008. Overview. Chapter 8 – Sampling Distributions and Estimation Confidence Intervals Binomial proportion ( p ) Sample size determination for a proportion ( p ). p (1- p ) n. s p =.

latifah-hamilton
Télécharger la présentation

BCOR 1020 Business Statistics

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. BCOR 1020Business Statistics Lecture 18 – March 20, 2008

  2. Overview • Chapter 8 – Sampling Distributions and Estimation • Confidence Intervals • Binomial proportion (p) • Sample size determination for a proportion (p)

  3. p(1-p)n sp = Chapter 8 – Confidence Interval for a Binomial Proportion (p) Estimating a binomial proportion: • Recall, an unbiased estimate of p in Bernoulli trials is… where X is the number of successes observed in n trials. • We can determine the mean (expected value) and • standard error (standard deviation) of this estimator… Since p is unknown, we often estimate this standard error with

  4. Chapter 8 – Confidence Interval for a Binomial Proportion (p) The Central Limit Theorem and the Sampling Distribution of p: • Also recall, that a Binomial random variable is • approximately normal if n is large. • Generally, if np> 10 and n(1 – p) > 10. • So, if n is sufficiently large, then our unbiased estimate of • p in these Bernoulli trials is also approximately normal. • p = is approximately normal with and

  5. Chapter 8 – Confidence Interval for a Binomial Proportion (p) The Central Limit Theorem and the Sampling Distribution of p: • Applying the standard normal transformation to p leads us to the conclusion that… is approximately a standard normal random variable! • Just as before, we can choose a value of the standard normal, za, such that P(-za < Z < za) = 100(1-a)% {95% for example} and use this to derive a confidence interval…

  6. Chapter 8 – Confidence Interval for a Binomial Proportion (p) Since P(-za < Z < za) = 100(1-a)% and Is the 100(1 – a)% Confidence Interval for p.

  7. As n increases, the statistic p = x/n more closely resembles a continuous random variable. As n increases, the distribution becomes more symmetric and bell shaped. As n increases, the range of the sample proportion p = x/n narrows. The sampling variation can be reduced by increasing the sample size n. Chapter 8 – Confidence Interval for a Binomial Proportion (p) Applying the CLT:

  8. A sample of 75 retail in-store purchases showed that 24 were paid in cash. What is p? Chapter 8 – Confidence Interval for a Binomial Proportion (p) Example Auditing: p = x/n = 24/75 = .32 • Is p normally distributed? np = (75)(.32) = 24 n(1-p)= (75)(.88) = 51 Both are > 10, so we may conclude normality.

  9. The 95% confidence interval for the proportion of retail in-store purchases that are paid in cash is: p(1-p)n p+z .32(1-.32) 75 = .32 + 1.96 Chapter 8 – Confidence Interval for a Binomial Proportion (p) Example Auditing: = .32 + .106 .214 < p < .426 • We are 95% confident that this interval contains the true population proportion.

  10. Clickers Suppose your business is planning on bringing a new product to market. At least 20% of your target market is willing to pay $25 per unit to purchase this product. If 200 people are surveyed and 44 say they would pay $25 to purchase this product, estimate p. (A) p = 0.11 (B) p = 0.22 (C) p = 0.44 (D) p = 0.50

  11. Clickers If 200 people are surveyed and 44 say they would pay $25 to purchase this product, is the sample large enough to treat p as normal? (A) Yes (B) No

  12. Clickers Find the z-value for a 95% C.I. on the binomial proportion, p. (A) = 1.282 (B) = 1.645 (C) = 1.960 (D) = 2.576

  13. Clickers Suppose your business is planning on bringing a new product to market. At least 20% of your target market is willing to pay $25 per unit to purchase this product. If 200 people are surveyed and 44 say they would pay $25 to purchase this product, find the 95% confidence interval for p. (A) (B) (C) (D)

  14. The width of the confidence interval for p depends on- the sample size- the confidence level- the sample proportion p To obtain a narrower interval (i.e., more precision) either- increase the sample size or- reduce the confidence level Chapter 8 – Sample Size Determination for a C. I. on p Narrowing the Interval:

  15. To estimate a population proportion with a precision of +E (allowable error), you would need a sample of size Chapter 8 – Sample Size Determination for a C. I. on p Sample Size Determination for a Proportion: • Since p is a number between 0 and 1, the allowable error E is also between 0 and 1. • Since p is unknown, we will either use • a prior estimate, p. • or the most conservative estimate p = ½.

  16. Chapter 8 – Sample Size Determination for a C. I. on p Example Auditing: • A sample of 75 retail in-store purchases showed that 24 were paid in cash. We calculated the 95% confidence interval for the proportion of retail in-store purchases that are paid in cash: = .32 + .106 or .214 < p < .426 • If we want to calculate a confidence interval that is no wider than + 0.05, how large should our sample be? • Using our estimate, p = 0.32, • Using the most conservative estimate, p = 0.5,

  17. Clickers Suppose your business is planning on bringing a new product to market. At least 20% of your target market is willing to pay $25 per unit to purchase this product. Using our earlier estimate, p = 0.22, determine how large our sample should be if we want a confidence interval no wider than E = + 0.05. (A) n = 40 (B) n = 264 (C) n = 338 (D) n = 1537

  18. A Look Ahead to Chapter 9 • Chapter 9 – Hypothesis Testing • Logic of Hypothesis Testing

  19. Chapter 9 – Logic of Hypothesis Testing • What is a statistical test of a hypothesis? • Hypotheses are a pair of mutually exclusive, collectively exhaustive statements about the world. • One statement or the other must be true, but they cannot both be true. • We make a statement (hypothesis) about some parameter of interest. • This statement may be true or false. • We use an appropriate statistic to test our hypothesis. • Based on the sampling distribution of our statistic, we can determine the error associated with our conclusion.

  20. Chapter 9 – Logic of Hypothesis Testing • 5 Components of a Hypothesis Test: • Level of Significance, a – maximum probability of a Type I Error • Usually 5% • Null Hypothesis, H0 – Statement about the value of the parameter being tested • Always in a form that includes an equality • Alternative Hypothesis, H1 – Statement about the possible range of values of the parameter if H0 is false • Usually the conclusion we are trying to reach (we will discuss.) • Always in the form of a strict inequality

  21. Chapter 9 – Logic of Hypothesis Testing • 5 Components of a Hypothesis Test: • Test Statistic and the Sampling Distribution of the Test statistic under the assumption that H0 is true • Z and T statistics for now • Decision Criteria – do we reject H0 or do we “accept” H0? • P-value of the test • or • Comparing the Test statistic to critical regions of its distribution under H0.

  22. Chapter 9 – Logic of Hypothesis Testing Error in a Hypothesis Test: • Type I error: Rejecting the null hypothesis when it is true. • a = P(Type I Error) = P(Reject H0 | H0 is True) • Type II error: Failure to reject the null hypothesis when it is false. • b = P(Type II Error) = P(Fail to Reject H0 | H0 is False)

More Related