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Lesson 6: Sampling Methods and the Central Limit Theorem

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-1

Outline

Point estimate Why sample the population?

Probability sampling Choice of sampling method: Sampling straws Sampling distribution of the sample means Probability histograms and empirical histograms Central Limit Theorem Normal approximation to Binomial

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-2

Point Estimates

Examples of point estimates are

   

the sample mean , the sample standard deviation , the sample variance , the sample proportion .

A point estimate is one value ( a single point ) that is used to estimate a population parameter.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-3

Estimating the percentage of Earth covered by water

  

Experiments:

Paint a dot on your thumb.

Catch the globe and tell me whether the dot on your thumb lands on water.

Estimate the percentage of Earth covered by water by the average of all trials.

Idea: If we draw many observations with replacement, the sample average will approach the population proportion. Code water as 1 and land as 0, the sample average will be an estimate of the proportion will be the percentage of Earth covered by water. Truth: Water covers 71% of the Earth's surface.

e.g., http://pao.cnmoc.navy.mil/educate/neptune/trivia/earth.htm

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-4

Why Sample the Population?

    

The physical impossibility of checking all items in the population.

The cost of studying all the items in a population.

The sample results are usually adequate.

Contacting the whole population would often be time consuming.

The destructive nature of certain tests.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-5

Probability Sampling

A probability sample is a sample selected such that each item or person in the population being studied has a known likelihood of being included in the sample.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-6

Methods of Probability Sampling

Simple Random Sample: item or person in the population has the same chance of being included.

A sample formulated so that each

Systematic Random Sampling: The items or individuals of the population are arranged in some order. A random starting point is selected and then every the population is selected for the sample.

k th member of

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-7

Methods of Probability Sampling

Stratified Random Sampling: into subgroups, called strata, and a sample is selected from each stratum. A population is first divided

Cluster Sampling: A population is first divided into primary units then samples are selected from the primary units.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-8

Independent identically distributed (iid)

  

“ random draws from any population, with replacement ” are independent identically distributed (i.i.d.) .

Independent: the probability of drawing the current observation does not depend on what has been drawn previously.

Identically distributed: the probability of drawing the current observation is the same as what has been drawn previously and what will be drawn in the future.

Most of the things covered in this Lesson holds even when we do not have iid observations.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-9

Choice of sampling method --

Sampling Straws

Choice of sampling method is important.

An exercise of “ Sampling Straws ” experiments will illustrate that some sampling method can produce a biased estimate of the population parameters.

   

The bag contain a total of 12 straws, 4 of which are 4 inches in length, 4 are 2 inches long, and 4 are 1 inch long.

The population mean length is 2.33 (=4*(1+2+4)/12) Randomly draw 4 straws one by one with replacement. Compute the sample mean.

The average of the sample means of experiments is generally larger than 2.33.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-10

Choice of sampling method --

Sampling Straws

 

The sample scheme is biased because the longer straws have a higher chance of being drawn, if the draw is truly random (say, draw your first touched straw).

The draw may not be random because we can feel the length of the straw before we pull out the straw.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-11

Choice of sampling method --

Sampling Straws

” 1 2 3 4 5 6 7 8 9 10 11 12

Alternative sampling scheme:

Label the straws 1 to 12.

  

Label 12 identical balls 1 to 12.

Draw four balls with replacement.

Measure the corresponding straws and compute the sample mean.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-12

Choice of sampling method --

Telephone interview

Suppose we are interested in estimating unemployment rate by a phone survey.

1.

Interview a group selected based on a random sample of mobile phone numbers.

2.

Interview a group selected based on a random sample of residential phone numbers.

3.

Interview a group selected based on a random sample of mobile and residential phone numbers.

Will we obtain a good estimate of the population unemployment rate?

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-13

Non-Probability Sampling

In nonprobability sample, whether an observation is included in the sample is based on the judgment of the person selecting the sample.

The sampling error is the difference between a sample statistic and its corresponding population parameter.

Sampling error is almost always nonzero .

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ECON1003: Analysis of Economic Data

Lesson6-14

Sampling Distribution of the Sample Means

The sampling distribution of the sample mean is a probability distribution consisting of all possible sample means of a given sample size selected from a population.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-15

EXAMPLE 1

The law firm of Hoya and Associates has five partners. At their weekly partners meeting each reported the number of hours they billed clients for their services last week.

 Partner 1. Dunn 2. Hardy 3. Kiers 4. Malinowski 5. Tillman

The population mean is 25.2 hours.

Hours 22 26 30 26 22   22  26  30  26  22  25 .

2 5 Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-16

Example 1

If two partners are selected randomly, how many different samples are possible? This is the combination of 5 objects taken 2 at a time. That is:

5

C

2  2 !

( 5 5 !

 2 )!

 10

There are a total of 10 different samples.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-17

Example 1

continued

Partners 1,2 1,3 1,4 1,5 2,3 2,4 2,5 3,4 2,4 2,5

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Total 48 52 48 44 56 52 48 56 52 48

ECON1003: Analysis of Economic Data

Mean 24 26 24 22 28 26 24 28 26 24

Lesson6-18

EXAMPLE 1

continued 

Organize the sample means into a frequency distribution.

Sample Mean Frequency 22 24 26 28 1 4 3 2 Relative Frequency probability 1/10 4/10 3/10 2/10

The mean of the sample means

X

 22 ( 1 )  24 ( 4 )  10 26 ( 3

is 25.2 hours.

)  28 ( 2 )  25 .

2

The mean of the sample means is exactly equal to the population mean.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-19

Example 1

Population variance = [ (22-25.2) 2 +(26-25.2) 2 + … + (22-25.2) 2 ] / 5 = 8.96

Variance of the sample means: =[ (1)(22-25.2) 2 +(4)(24-25.2) 2 25.2) 2 ] / ( 1+2+3+2) = 3.36

+ (3)(26-25.2) 2 + (2)(22-

The variance of sample means < variance of population variance

3.36/8.96 = 0.375 <1 Note that this is like sampling without replacement.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-20

Example

Suppose we had a uniformly distributed population containing equal proportions (hence equally probable instances) of (0,1,2,3,4). If you were to draw a very large number of random samples from this population, each of size n=2, the possible combinations of drawn values and the sums are Sums Combinations 0 0,0 1 2 3 4 0,1 1,0 1,1 2,0 0,2 1,2 2,1 3,0 0,3 1,3 3,1 2,2 4,0 0,4 5 6 7 8 1,4 4,1 3,2 2,3 3,3 4,2 2,4 3,4 4,3 4,4 Note that this is sampling with replacement.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-21

Example

Population mean = mean of sample means

Population mean = (0+1+2+3+4)/5=2

Mean of sample means = [ (1)(0) + (2)(0.5) + …+(1)(4) ] / 25 = 2 Means 0.0

Variance of sample means = Population variance/ sample size 0.5

1.0

Population variance =(0-2) 2 + … + (4-2) 2 / 5 = 2 1.5

2.0

2.5

Variance of sample means =(1)(0-2) 2 +… +(1)(4-2) 2 / 25 =1

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

3.0

3.5

4.0

Combinations 0,0 0,1 1,0 1,1 2,0 0,2 1,2 2,1 3,0 0,3 1,3 3,1 2,2 4,0 0,4 1,4 4,1 3,2 2,3 3,3 4,2 2,4 3,4 4,3 4,4

Lesson6-22

Probability Histograms

In a probability histograms, the area of the bar represents the chance of a value happening as a result of the random (chance) process

Empirical histograms (from observed data) for a process converge to the probability histogram

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-23

Examples of empirical histogram

Roll a fair die: 50, 200 times

30

50 times

20 30 20

200 times

10 10 0 0 1 2 3 4 5 6 1 2 3 4 5 DIE DIE

The empirical histogram will approach the probability histogram as the number of draws increase.

6 Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-24

Empirical histogram #1

Two balls in the bag: Draw 1 ball 1000 times with replacement. Plot a relative frequency histogram ( empirical probability histogram ).

0.5

The empirical histogram looks like the population distribution !!!

What is the probability of getting a red ball in any single draw?

0.5

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-25

Empirical histogram #2

5 balls in the bag: Draw 1 ball 1000 times with replacement. Plot a relative frequency histogram ( empirical probability histogram ).

0.6

0.4

The empirical histogram looks like the population distribution !!!

What is the probability of getting a red ball in any single draw?

0.6

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-26

Empirical histogram #3

5 balls in the bag: 0 1 2 3 4 Draw 1 ball 1000 times with replacement. Plot a relative frequency histogram ( empirical probability histogram ).

The empirical histogram looks like the population distribution !!!

What is the probability of getting a “three” in any single draw?

0.2

0.2

What is the expected value (i.e., population mean) of a single draw?

0.2*0 + 0.2*1 + … + 0.2*4 = 2 Variance = 0.2*(-2) 2 +… +0.2*(2) 2 = 2 + 0.2*(-1) 2 0

Ka-fu Wong © 2004

1 2 3 4

ECON1003: Analysis of Economic Data

Lesson6-27

Empirical histogram #3

continued 5 balls in the bag: 0 1 2 3 4 Draw 2 balls 1000 times with replacement. Compute the sample mean. Plot a relative frequency histogram ( empirical probability histogram ) of the 1000 sample means.

Means 0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

Ka-fu Wong © 2004

Combinations All combinations are equally likely.

0,0 0,1 1,0 1,1 2,0 0,2 1,2 2,1 3,0 0,3 1,3 3,1 2,2 4,0 0,4 1,4 4,1 3,2 2,3 3,3 4,2 2,4 3,4 4,3 4,4 0.2

0.18

0.16

0.14

0.12

0.1

0.08

0.06

0.04

0.02

0 0 0.5

ECON1003: Analysis of Economic Data

1 1.5

2 2.5

3 3.5

4

Lesson6-28

Empirical histogram #3

continued 5 balls in the bag: 0 1 2 3 4 0.2

0.18

0.16

0.14

0.12

0.1

0.08

0.06

0.04

0.02

0 Draw 2 ball 1000 times with replacement. Compute the sample mean. Plot a relative frequency histogram ( empirical probability histogram ) of the 1000 sample means.

What is the probability of getting a sample mean of 2.5 in any single draw?

0.16

0 0.5

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1 1.5

What is the expected sample mean of a single draw?

0.04*0 + 0.08*0.5 +… + 0.04*4 = 2 2 2.5

3 3.5

4 Variance of sample mean = 0.04*(-2) 2 + 0.08 *(-1.5) 2 + … + 0.04*(2) 2 = 1

ECON1003: Analysis of Economic Data

Lesson6-29

Distribution of Sample means of different sample sizes and from different population distribution

http://www.ruf.rice.edu/~lane/stat_sim/sampling_dist/i ndex.html

http://www.kuleuven.ac.be/ucs/java/index.htm

choose basic and distribution of mean.

and

http://faculty.vassar.edu/lowry/central.html

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-32

Central Limit Theorem #1

5 balls in the bag: 0 1 2 3 4 Draw n (n>30) ball 1000 times with replacement. Compute the sample mean. Plot a relative frequency histogram ( empirical probability histogram ) of the 1000 sample means.

The Central Limit Theorem says 1.

The empirical histogram looks like a normal density.

2.

3.

Expected value (mean of the normal distribution) = mean of the original population mean = 2.

Variance of the sample means = variance of the original population /n = 2/n.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-33

Central Limit Theorem #2

Some unknown number of numbered balls in the bag: 0 1 2 3 4 ?

?

We know only that the population mean is

and the variance is

2 .

Draw n (n>30) ball 1000 times with replacement. Compute the sample mean. Plot a relative frequency histogram ( empirical probability histogram ) of the 1000 sample means.

The Central Limit Theorem says 1.

The empirical histogram looks like a normal density.

2.

3.

Expected value (mean of the normal distribution) = Variance of the sample means =

2 /n.

.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-34

Confidence interval #1

Some unknown number of numbered balls in the bag: 0 1 2 3 4 ?

?

We know only that the population mean is

and the variance is

2 .

The Central Limit Theorem says 1.

The empirical histogram looks like a normal density.

2.

3.

Expected value (mean of the normal distribution) = Variance of the sample means =

2 /n.

.

What is the probability that the sample mean of a randomly drawn sample lies between

  

/

n ?

0.6826

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-35

Central Limit Theorem

For a population with a mean

and a variance

2 the sampling distribution of the means of all possible samples of size n generated from the population will be approximately normally distributed .

The mean of the sampling distribution equal to

variance equal to

2 / n.

and the The population distribution

X

~

N

(  ,  2 )

The sample mean of n observation

X n

~

N

(  ,  2 /

n

) Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-36

Central Limit Theorem: Sums

For a large number of random draws, with replacement, the distribution of the sum approximately follows the normal distribution

 

Mean of the normal distribution is

n* (expected value of one random draw) SD for the sum (SE) is

n

  

This holds even if the underlying population is not normally distributed

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-37

Central Limit Theorem: Averages

For a large number of random draws, with replacement, the distribution of the average = (sum)/n approximately follows the normal distribution

The mean for this normal distribution is

 

(expected value of one random draw) The SD for the average (SE) is

n

This holds even if the underlying population is not normally distributed

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-38

Law of large numbers

The sample mean converges to the population mean as n gets large.

For a large number of random draws from any population, with replacement, the distribution of the average = (sum)/n approximately follows the normal distribution

The mean for this normal distribution is the (expected value of one random draw)

The SD for the average (SE) is

n

SD for the average tends to zero as n increases.

This holds even if the underlying population is not normally distributed

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ECON1003: Analysis of Economic Data

Lesson6-39

Central Limit Theorem Simulation

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Lesson6-40

Effect of Sample Size

Regardless of the underlying population means.

, the larger the sample size, the more nearly normally distributed is the population of all possible sample

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ECON1003: Analysis of Economic Data

Lesson6-41

Central Limit Theorem

 

If a population follows the normal distribution the normal distribution.

, the sampling distribution of the sample mean will also follow To determine the probability a sample mean falls within a particular region, use:

z

X

  

n

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-42

Central Limit Theorem

 

If the population does not follow the normal distribution , but the sample is of at least 30 observations , the sample means will follow the normal distribution.

To determine the probability a sample mean falls within a particular region, use:

z

X s

 

n

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-43

Example 2

Suppose the mean selling price of a gallon of gasoline in the United States is $1.30. Further, assume the distribution is positively skewed, with a standard deviation of $0.28. What is the probability of selecting a sample of 35 gasoline stations and finding the sample mean within $.08 of the population mean ($1.30)?

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-44

Example 2

continued 

The first step is to find the $1.22 (=1.30-0.08) and $1.38 (=1.30+0.08). These are the two points within $0.08 of the population mean.

z -values corresponding to

z

X s

 

n

 $ 1 .

38  $ 1 .

30 $ 0 .

28 35  1 .

69

z

X s

 

n

 $ 1 .

22  $ 1 .

30 $ 0 .

28 35   1 .

69 Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-45

Example 2

continued 

Next we determine the probability of a z value between -1.69 and 1.69. It is:

P

(  1 .

69 

z

 1 .

69 )  2 (.

4545 )  .

9090 

We would expect about 91 percent of the sample means to be within $0.08 of the population mean.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-46

Sampling Distribution of Sample Proportion

If a random sample of size n is taken from a population then the sampling distribution of the

is Approximately normal, if n is large.

Has mean

 pˆ = p

Has standard deviation

 pˆ = p(1 p) n

Approximately normal because the sample proportion is a simple average of zeros and ones from difference trials.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-47

The Normal Approximation to the Binomial

revisited  

The normal distribution (a continuous distribution) yields a good approximation of the binomial distribution (a discrete distribution) for large values of n. The normal probability distribution is generally a good approximation to the binomial probability distribution when n

and n(1-

) are both greater than 5.

iid Recall for the binomial experiment:

There are only two mutually exclusive outcomes (success or failure) on each trial.

 

A binomial distribution results from counting the number of successes.

Each trial is independent.

The probability is fixed from trial to trial, and the number of trials n is also fixed.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-48

The Normal Approximation to the Binomial

revisited

Recoding: Failure as 0 and success as 1.

x/n is simply the proportion of success and hence the simple average of the outcomes from the n trials.

x/n will be approximately normal according to CLT.

Hence x (=n*x/n) will also be approximately normal according to CLT.

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-49

Lesson 6:

Sampling Methods and the Central Limit Theorem

- END -

Ka-fu Wong © 2004

ECON1003: Analysis of Economic Data

Lesson6-50