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Source: J. Hollenbeck

Sampling Designs. Avery and Burkhart, Chapter 3. Source: J. Hollenbeck. Why Not Measure Everything?. Complete Enumeration (Census). Measure every feature of interest. The result is a highly accurate description of the population. Drawbacks: Only viable with small populations.

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Source: J. Hollenbeck

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  1. Sampling Designs Avery and Burkhart, Chapter 3 Source: J. Hollenbeck

  2. Why Not Measure Everything? Complete Enumeration (Census) Measure every feature of interest. The result is a highly accurate description of the population. Drawbacks: Only viable with small populations. Only cost-effective with high-valued features. FOR 220 Aerial Photo Interpretation and Forest Measurements

  3. Why Not Randomly Select Samples? • We will discuss several sampling designs in this lecture • Most statistical methods assume simple random sampling was used. • Sampling methods, however, will vary depending on the objectives of the survey, the nature of the population being sampled, and prior information about the population being sampled. FOR 220 Aerial Photo Interpretation and Forest Measurements

  4. Sampling Designs Sampling Designs Covered Today: • Simple Random Sampling • Systematic Sampling • Stratified Random Sampling FOR 220 Aerial Photo Interpretation and Forest Measurements

  5. Sampling Design I: Simple Random Sampling Assumptions: Every possible combination of sampling units has an equal and independent chance of being selected. The selection of a particular unit to be sampled is not influenced by the other units that have been selected or will be selected. Samples are either chosen with replacement or without replacement. FOR 220 Aerial Photo Interpretation and Forest Measurements

  6. Sampling Design I: Simple Random Sampling Design: FOR 220 Aerial Photo Interpretation and Forest Measurements

  7. Sampling Design I: Simple Random Sampling We use the familiar equations for estimating common statistics for the population Estimate the population mean: Estimate the variance of individual values: Compute the coefficient of variation: FOR 220 Aerial Photo Interpretation and Forest Measurements

  8. Sampling Design I: Simple Random Sampling Compute the standard error: OR (with replacement, or infinite population) (without replacement and from a finite population) Compute confidence limits: t = t statistic from table, determined by degrees of freedom (n-1). In general, it is safe to use: t = 2.0 for small n (n < 30), or t = 1.96 for large n (n > 30) if you do not have access to a t-table. FOR 220 Aerial Photo Interpretation and Forest Measurements

  9. Sampling Design I: Simple Random Sampling How many samples to take? • Sample size should be statistically and practically efficient. • Enough sample units should be measured to obtain the desired level of precision (no more, no less). FOR 220 Aerial Photo Interpretation and Forest Measurements

  10. Sampling Design I: Simple Random Sampling Determine sample size (withoout replacement, or finite population): Knowing the coefficient of variation and that error is expected to be within x % of the value of the mean, we use the following forumula n = where, n = required sample size, A = allowable error percent, t = t-value, CV = coefficient of variation, and N = population size

  11. Sampling Design I: Simple Random Sampling Determine sample size (withoout replacement, or finite population): • Example using 0.10 ac fixed radius plots in a ten acre stand • Assume: • We have calculated theCV and found it was 30% • Our allowable error is +/- 10% of the mean • Are using t-value of 2 • N is the total number of potential plots that could be placed in the stand (i.e., population). • In this case, N is stand size/plot size or 10/0.10 = 100 n = = 26 n =

  12. Sampling Design II: Systematic Sampling Assumptions: The initial sampling unit is randomly selected or established on the ground. All other sample units are spaced at uniform intervals throughout the area sampled. Sampling units are easy to locate. Sampling units appear to be representative of an area. FOR 220 Aerial Photo Interpretation and Forest Measurements

  13. Sampling Design II: Systematic Sampling Design: A Grid Scheme is most common FOR 220 Aerial Photo Interpretation and Forest Measurements

  14. Sampling Design II: Systematic Sampling Arguments: For: Regular spacing of sample units may yield efficient estimates of populations under certain conditions. *** Against: Accuracy of population estimates can be low if there is periodic or cyclic variation inherent in the population. FOR 220 Aerial Photo Interpretation and Forest Measurements

  15. Sampling Design II: Systematic Sampling Arguments: For: There is no practical alternative to assuming that populations are distributed in a random order across the landscape. Against: Simple random sampling statistical techniques can’t logically be applied to a systematic design unless populations are assumed to be randomlydistributed across the landscape. FOR 220 Aerial Photo Interpretation and Forest Measurements

  16. Sampling Design II: Systematic Sampling Summary: We can (and often do) use systematic sampling to obtain estimates about the mean of populations. When an objective, numerical statement of precision is required, however, it should be viewed as an approximation of the precision of the sampling effort. (i.e. 95% confidence intervals) Use formulas presented for simple random sampling, and where appropriate, use the “without replacement” variations of those equations (if sampling from a small population), otherwise use the normal SRS statistical techniques. FOR 220 Aerial Photo Interpretation and Forest Measurements

  17. Sampling Design III: Stratified Random Sampling Assumptions: A population is subdivided into subpopulations of known sizes. A simple random sample of at least two units is drawn from each subpopulation. Why? To obtain a more precise estimate of the population mean. If the variation within a subpopulation is small in relation to the total population variance, the estimate of the population mean will be considerably more precise than a simple random sample of the same size. Why? To obtain an estimate of the resources within the subpopulations. FOR 220 Aerial Photo Interpretation and Forest Measurements

  18. Sampling Design III: Stratified Random Sampling Design: FOR 220 Aerial Photo Interpretation and Forest Measurements

  19. Sampling Design III: Stratified Random Sampling Estimate the overall population mean: Where: L = number of strata Nh = total number of [area] units in strata h N = total number of [area] units in all strata << Essentially a weighted average >> We often use area for strata units (acres, hectares) in natural resource applications FOR 220 Aerial Photo Interpretation and Forest Measurements

  20. Strata acres mean dbh 1 10 12.2 2 12 31.6 3 7 20.1 Sampling Design III: Stratified Random Sampling Estimate the overall population mean: Example: FOR 220 Aerial Photo Interpretation and Forest Measurements

  21. Sampling Design III: Stratified Random Sampling Calculating Sample Size for Stratified Random Sample: Specify the sampling error objective for tract as a whole Subdivide (stratify) the tract (i.e., population) into sampling components. The purpose is to reduce the coefficient of variation within the sampling strata. Calculate coefficient of variation by stratum and a weighted CV over all strata. Calculate number of plots for the sale as a whole, then allocate by stratum

  22. Sampling Design III: Stratified Random Sampling Calculating Sample Size for Stratified Random Sample: An Illustrative Example

  23. Sampling Design III: Stratified Random Sampling

  24. Sampling Design III: Stratified Random Sampling

  25. Sampling Design III: Stratified Random Sampling

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