Experiment With Sample Sizes Close To Population - How To Approach Inference? (+FPC)

Experiment with Sample Sizes Close to Population - How to Approach Inference? (+FPC)

When conducting experiments or surveys, researchers often face the challenge of determining the optimal sample size. While a larger sample size typically provides more accurate results, it can be impractical or even impossible to collect data from the entire population. In such cases, researchers may consider using a sample size that is close to the population size. However, this approach raises important questions about how to approach inference and whether the results can be generalized to the larger population.

Understanding the Finite Population Correction (FPC)

The Finite Population Correction (FPC) is a statistical technique used to adjust the standard error of a sample when the sample size is close to or equal to the population size. The FPC is particularly important in situations where the sample size is a significant proportion of the population, as it can lead to biased estimates and incorrect inferences.

The Problem of Inference

When the sample size is close to the population size, the traditional methods of inference, such as hypothesis testing and confidence intervals, may not be applicable. This is because the standard errors of the estimates are inflated due to the finite population correction, making it difficult to determine the significance of the results.

Approaches to Inference with FPC

There are several approaches to inference when working with sample sizes close to the population size:

1. Use of Bootstrap Methods

Bootstrap methods involve resampling the data with replacement to estimate the standard error of the estimates. This approach can provide a more accurate estimate of the standard error, even when the sample size is close to the population size.

2. Use of Jackknife Methods

Jackknife methods involve leaving out one observation at a time and estimating the standard error of the estimates. This approach can also provide a more accurate estimate of the standard error, especially when the sample size is close to the population size.

3. Use of FPC-Adjusted Standard Errors

FPC-adjusted standard errors involve adjusting the standard error of the estimates by the finite population correction. This approach can provide a more accurate estimate of the standard error, especially when the sample size is close to the population size.

4. Use of Bayesian Methods

Bayesian methods involve using prior distributions to estimate the standard error of the estimates. This approach can provide a more accurate estimate of the standard error, especially when the sample size is close to the population size.

Example: Experiment in All Schools of a Small Country

Let's consider an example where we are conducting an experiment in all schools of a small country. We want to estimate the average score of students in mathematics. The population size is 100 schools, and we have collected data from 95 schools. We want to estimate the average score of students in mathematics using the sample data.

Step 1: Calculate the Sample Mean

We calculate the sample mean of the scores as follows:

School ID	Score
1	80
2	85
3	90
...	...
95	95

Sample Mean = (80 + 85 + ... + 95) / 95 = 88.2

Step 2: Calculate the FPC-Adjusted Standard Error

We calculate the FPC-adjusted standard error of the sample mean as follows:

FPC-Adjusted Standard Error = sqrt((1 - (95/100)^2) * (s^2 / 95))

where s^2 is the sample variance of the scores.

FPC-Adjusted Standard Error = sqrt((1 - (95/100)^2) * (10^2 / 95)) = 1.1

Step 3: Calculate the Confidence Interval

We calculate the confidence interval of the sample mean as follows:

Confidence Interval = (Sample Mean - (Z * FPC-Adjusted Standard Error), Sample Mean + (Z * FPC-Adjusted Standard Error))

where Z is the Z-score corresponding to the desired confidence level.

Confidence Interval = (88.2 - (1.96 * 1.1), 88.2 + (1.96 * 1.1)) = (85.1, 91.3)

In conclusion, when conducting experiments or surveys with sample sizes close to the population size, it is essential to use the finite population correction to adjust the standard error of the estimates. The approaches to inference with FPC, such as bootstrap methods, jackknife methods, FPC-adjusted standard errors, and Bayesian methods, can provide a more accurate estimate of the standard error and confidence interval. By using these approaches, researchers can make more informed decisions and draw more accurate conclusions from their data.

• Cochran, W. G. (1977). Sampling techniques. John Wiley & Sons.
• Kish, L. (1965). Survey sampling. John Wiley & Sons.
• Rao, J. N. K. (2003). Small area estimation. John Wiley & Sons.
• Särndal, C. E., & Swensson, B. (1987). A calibration estimator for survey sampling. Biometrika, 74(3), 419-426.
  Experiment with Sample Sizes Close to Population - How to Approach Inference? (+FPC) - Q&A

In our previous article, we discussed the challenges of conducting experiments or surveys with sample sizes close to the population size. We also explored the importance of using the finite population correction (FPC) to adjust the standard error of the estimates. In this article, we will answer some frequently asked questions (FAQs) related to this topic.

Q: What is the finite population correction (FPC)?

A: The finite population correction (FPC) is a statistical technique used to adjust the standard error of a sample when the sample size is close to or equal to the population size. The FPC is particularly important in situations where the sample size is a significant proportion of the population, as it can lead to biased estimates and incorrect inferences.

Q: Why is the FPC necessary?

A: The FPC is necessary because when the sample size is close to the population size, the standard error of the estimates is inflated due to the finite population correction. This can lead to biased estimates and incorrect inferences.

Q: What are some common approaches to inference with FPC?

A: Some common approaches to inference with FPC include:

• Bootstrap methods: Resampling the data with replacement to estimate the standard error of the estimates.
• Jackknife methods: Leaving out one observation at a time and estimating the standard error of the estimates.
• FPC-adjusted standard errors: Adjusting the standard error of the estimates by the finite population correction.
• Bayesian methods: Using prior distributions to estimate the standard error of the estimates.

Q: How do I calculate the FPC-adjusted standard error?

A: To calculate the FPC-adjusted standard error, you need to follow these steps:

1. Calculate the sample variance of the estimates.
2. Calculate the finite population correction (FPC) using the formula: FPC = sqrt((1 - (n/N)^2) * (s^2 / n))
3. Calculate the FPC-adjusted standard error using the formula: FPC-Adjusted Standard Error = sqrt((1 - (n/N)^2) * (s^2 / n))

Q: What is the difference between the FPC and the standard error?

A: The FPC is a correction factor that is used to adjust the standard error of the estimates when the sample size is close to the population size. The standard error is a measure of the variability of the estimates, while the FPC is a correction factor that is used to adjust the standard error.

Q: Can I use the FPC with other statistical methods?

A: Yes, the FPC can be used with other statistical methods, such as regression analysis, time series analysis, and hypothesis testing.

Q: What are some common applications of the FPC?

A: Some common applications of the FPC include:

• Survey sampling: The FPC is used to adjust the standard error of the estimates in survey sampling.
• Experimental design: The FPC is used to adjust the standard error of the estimates in experimental design.
• Time series analysis: The FPC is used to adjust the standard error of the estimates in time series analysis.

In conclusion, the finite population correction (FPC) is an important statistical technique that is used to adjust the standard error of the estimates when the sample size is close to the population size. By using the FPC, researchers can make more informed decisions and draw more accurate conclusions from their data. We hope that this Q&A article has provided you with a better understanding of the FPC and its applications.

• Cochran, W. G. (1977). Sampling techniques. John Wiley & Sons.
• Kish, L. (1965). Survey sampling. John Wiley & Sons.
• Rao, J. N. K. (2003). Small area estimation. John Wiley & Sons.
• Särndal, C. E., & Swensson, B. (1987). A calibration estimator for survey sampling. Biometrika, 74(3), 419-426.