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Estimation in Sampling

Estimation in Sampling. GTECH 201 Lecture 15. Conceptual Setting. How do we come to conclusions from empirical evidence? Isn’t common sense enough? Why? Systematic methods for drawing conclusions from data Statistical inference Inductive versus Deductive Reasoning. Drawing Conclusions.

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Estimation in Sampling

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  1. Estimation in Sampling GTECH 201 Lecture 15

  2. Conceptual Setting • How do we come to conclusions from empirical evidence? • Isn’t common sense enough? • Why? • Systematic methods for drawing conclusions from data • Statistical inference • Inductive versus Deductive Reasoning

  3. Drawing Conclusions • Statistical inference • Based on the laws of probability • What would happen if? • You ran your experiment hundreds of times • You repeated your survey over and over again • Statistic and Parameter • The proportion of the population who are <disabled> usually denoted by: p • In a SRS of 1000 people, the proportion of the people who are <disabled> usually denoted by: (p -hat)

  4. Estimating with Confidence • Say you are conducting an opinion poll… • SRS of 1000 adult television viewers • You ask these folks if they trust Walter Cronkite when he delivers the nightly news • Out of 1000, 570 say, they trust him • 57% of the people trust Walter • is 0.57 • If you collect another set of 1000 television viewers, what will the rating be?

  5. Confidence Statement • We need to add a confidence statement • We need to say something about the margin of error • Confidence statements are based on the distribution of the values of the sample proportion that would occur if many independent SRS were taken from the same population • The sampling distribution of the statistic

  6. Terminology Review • Sample • Population • Statistic • a numerical characteristic associated with a sample • Parameter • A numerical characteristic associated with the population • Sampling error • The need for interval estimation

  7. Point Estimation • Point estimation of a parameter is the value of a statistic that is used to estimate the parameter • Compute statistic (e.g., mean) • Use it to estimate corresponding population parameter • Point Estimators of Population Parameters(see next slide)

  8. Point Estimators for Population Parameters Population Sample Calculating Parameter statistic formula

  9. Interval Estimation • Sample point estimators are usually not absolutely precise • How close or how distant is the calculated sample statistic from the population parameter • We can say that the sample statistic is within a certain range or interval of the population parameter. • The determination of this range is the basis for interval estimation

  10. Interval Estimation (2) • A confidence interval (CI) represents the level of precision associated with a population estimate • Width of the interval is determined by • Sample size, • variability of the population, and • the probability level or the level of confidence selected

  11. Sampling Distributionof the Mean • The distribution of all possible sample means for a sample of a given size • Use the mean of a sample to estimate and draw conclusions about the mean of that entire population • So we have samples of a particular size • We need formulas to determine the mean and the standard deviation of all possible sample means for samples of a given size from a population

  12. Sample and Population Mean • For samples of size n, mean of the variable • Is equal to the mean of the variable under consideration • Mean of all possible sample means is equal to the population mean

  13. Sample Standard Deviation • For samples of size n, the standard deviation of the variable • Is equal to the standard deviation of the variable under consideration, divided by the square root of the sample size • For each sample size, the standard deviation of all possible sample means equals the population standard deviation divided by the square root of the sample size

  14. Central Limit Theorem • Suppose all possible random samples of size n are drawn from an infinitely large, normally distributed population having a mean and a standard deviation • The frequency distribution of these sample means will have: • A mean of (the population mean) • A normal distribution around this population mean • A standard deviation of

  15. Sampling Error • Standard Error of the mean (SEM) is a basic measure for the amount of sampling error • SEM indicates how much a typical sample mean is likely to differ from a true population mean • Sample size, and population standard deviation affect the sampling error

  16. Sampling Error (2) • The larger the sample size, the smaller the amount of sampling error • The larger the standard deviation, the greater the amount of sampling error

  17. Finite Population Correction Factor • The frequency distribution of the sample means is approximately normal if the sample size is large • N < 30 (small sample); N > 30 (large sample) • If you have a finite population, then you need to introduce a correction, i.e., the fpc rule/factor in the estimation process • where fpc = finite population correction; • n = sample size; • N = population size

  18. Standard Error of the Mean for Finite Populations When including the fpc should be: In general, you include the fpc in the population estimates only when the ratio of sample size to population size exceeds 5 % or when n / N > 0.05

  19. Constructing Confidence Intervals • A random sample of 50 commuters reveals that their average journey-to-work distance was 9.6 miles • A recent study has determined that the std. deviation of journey-to-work distance is approximately 3 miles • What is the CI around this sample mean of 9.6 that guarantees with 90 % certainty that the true population mean is enclosed within that interval?

  20. Confidence Intervalfor the Mean • Z value associated with a 90 % confidence level (Z =1.65) • The sample mean is the best estimate of the true population mean • CI = • 9.6 +1.65 (3/ ) = 10.30 miles • 9.6 - 1.65 (3/ ) = 8.90 miles

  21. Confidence Interval • We say that the sample statistic is within a certain range or interval of the population parameter • e.g., in our sample, 57% of the viewers thought Walter Cronkite is trustworthy • In the general population, between 54% and 60% of viewers think that Walter Cronkite is trustworthy • Or, in our sample, the average commuting distance was 9.6 miles • In the population, we calculated that the average commute is likely to be somewhere between 8.9 miles and 10.3 miles

  22. Confidence Level • Gives you an understanding of how reliable your previous statement regarding the confidence interval is • The probability that the interval actually includes the population parameter • For example, the confidence level refers to the probability that the interval (8.9 miles to 10.3 miles) actually encompasses the TRUE population mean (90%, 95%, 99.7%) • Confidence Level probability is 1 - 

  23. Significance Level •  (alpha) • The probability that the interval that surrounds the sample statistic DOES NOT include the population parameter • E.g., the probability that the average commuting distance does not fall between 8.9 miles and 10.3 miles •  = 0.10 (90%); 0.05 (95%); 0.01 (99.7%) • Confidence Interval width -- increases

  24. Sampling Error • Total sampling error =  • Probability that the sample statistic will fall into either tail of the distribution is: /2 • If you want 99.7% confidence (i.e., low error), then you have to settle for giving a less precise estimate (the CI is wider)

  25. If the Standard Deviationis Unknown • If we don’t know the population mean, its likely we don’t know the standard deviation • What you are likely to have is the variance and standard deviation of your sample • Also, you have a small population, so you have to use the finite population correction factor that was discussed earlier • Once you have the formula for standard error, then you can proceed as before to determine the confidence interval

  26. Standard Error

  27. Student’s T Distribution • William Gosset (1876-1937) • Published his contributions to statistical theory under a pseudonym • Student’s t distribution is used in performing inferences for a population mean, when, • The population being sampled is approximately normally distributed • The population standard deviation is unknown • And the sample size is small (n < 30)

  28. Characteristics of the t - Distribution • A t curve is symmetric, bell shaped • Exact shape of distribution varies with sample size • When n nears 30, the value of t approaches the standard normal Z value • A particular distribution is identified by defining its degrees of freedom (df) • For a t distribution, df = (n -1)

  29. Properties of t Curves • The total area under a t curve = 1 • A t curve extends indefinitely in both directions, approaching, but never touching the horizontal axis • A t-curve is symmetrical about 0 • As the degrees of freedom become larger, t curves look increasingly like the standard normal curve • We need to use a t-table and look for values of t, instead of Z to determine the confidence interval

  30. Calculating various CIs • Sampling • SRS, systematic, or stratified • Parameters • Mean, total, or proportion • Six situations • Consider whether to use fpc • when n/N > 0.05 • Consider whether to use Z or t • when n < 30

  31. If Random or Systematic Sample • Estimate of Population Mean • Best estimate is ? • Estimate of sampling error • Standard error of the mean (inc. fpc)

  32. If Stratified Sample • Estimate of population mean • Still equal to sample mean but… • Std. Error of the mean (inc. fpc) Where m=number of strata; i= refers to a particular stratum

  33. Minimum Sample Size • Before going out to the field, you want to know how big the sample ought to be for your research problem • Sample must be large enough to achieve precision and CI width that you desire • Formulas to determine the three basic population parameters with random sampling

  34. Sample Size Selection - Mean • Your goal is to determine the minimum sample size • You want to situate the estimated population mean, in a specified CI E = amount of error you are willing to tolerate

  35. Example 1 • We are looking at Neighborhood X • 3,500 households • Sample size = 25 households • Sample mean = 2.73 • Sample variance = 2.6 • CI = 90% • Find the mean number of people per household

  36. Example 2 • Sample of 30 households • Sample standard deviation is 1.25 • What sample size is needed to estimate the mean number of persons per household in neighborhood X • and be 90% confident that your estimate will be within 0.3 persons of the true population mean?

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