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August 2012

This month's newsletter is the first in a multi-part series on using

the ANOVA method for an ANOVA Gage R&R study. This

method simply uses analysis of variance to analyze the results of

a gage R&R study instead of the classical average and rangemethod. The two methods do not generate the same results, but

they will (in most cases) be similar.

This newsletter focuses on part of the ANOVA table and how it is developed for the

Gage R &R study. In particular it focuses on the sum of squares and degrees of

freedom. Many people do not understand how the calculations work and the

information that is contained in the sum of squares and the degrees of freedom. In

the next few issues, we will put together the rest of the ANOVA table and complete

the Gage R&R calculations.

In this issue: Sources of Variation

Example Data

The ANOVA Table for Gage R&R

The ANOVA Results

Total Sum of Squares and Degrees of Freedom

Operator Sum of Squares and Degrees of Freedom

Parts Sum of Squares and Degrees of Freedom

Equipment (Within) Sum of Squares and Degrees of Freedom

Interaction Sum of Squares and Degrees of Freedom

Summary

Quick Links

Any gage R&R study is a study of variation. This means you have to have variation

in the results. On occasion, I get a phone call from a customer wondering why their

Gage R&R study is not giving them any useful information. And, in looking at the

results, I discover that each result is the same - for each part and for each

operator. There is no variation. I am asked - Isn't it good that there is no variation in

the results? No, not in a gage R&R study. It means that the measurement process

cannot tell the difference between the samples. So remember, a gage R&R study

is a study in variation - this means that there must be variation.

If you are not familiar with how to conduct a Gage R&R study, please see our

December 2007 newsletter. This newsletter also includes how to analyze the

results using the average and range method.

As usual, please feel free to leave comments at the end of the newsletter.

Sources of Variation

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Suppose you are monitoring a process by pulling samples

of the product at some regular interval and measuring one

critical quality characteristic (X). Obviously, you will not

always get the same result when measure for X. Why

not? There are many sources of variation in the process.However, these sources can be grouped into three

categories:

variation due to the process itself

variation due to sampling

variation due to the measurement system

These three components of variation are related by the following:

where t2is the total process variance; p

2is the process variance; s

2is the

sampling variance and ms2is the measurement system variance. Note that the

relationship is linear in terms of the variance (which is the square of the standard

deviation), not the standard deviation.

For our purposes here, we will ignore the variance due to sampling (or more

correctly, just include it as part of the process itself). However, for some processes,

sampling variation can greatly impact the results. Thus, we will consider the total

variance to be:

Remember geometry? The right triangle? The Pythagorean Theorem? The above

equation can be represented by the triangle below.

The total standard deviation, t, for a measurement is equal to the length of the

hypotenuse. The process standard deviation, p, is equal to the length of one side

of the triangle and the measurement system standard deviation, ms, is equal to the

length of the remaining side.

You can easily see from this triangle what happens as the variation in the product

and measurement system changes. If the product standard deviation is larger than

the measurement standard deviation, it will have the larger impact on the total

standard deviation. However, if the measurement standard deviation becomes too

large, it will begin to have the largest impact.

Thus, the objective of improving a measurement system is to minimize the %

variance due to the measurement system:

% Variance due to measurement system = 100(ms2/t

2)

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The gage R&R study focuses on ms2. In a gage R&R study, you can break down

ms2into its two components:

Repeatabilityis the ability of the measurement system to repeat the same

measurements on the same sample under the same conditions. It represents an

assessment of the ability to get the same measurement result each time.

Reproducibilityis the ability of measurement system to return consistent

measurements while varying the measurement conditions (different operators,

different parts, etc.) It represents an assessment of the ability to reproduce the

measurement of other operators.

In this series, we will take a look at how the repeatability and reproducibility are

determined using the ANOVA method for Gage R&R.

Example DataWe will re-use the data from our December 2007 newsletter on the average and

range method for Gage R&R. In this example, there were three operators who

tested five parts three times. A picture of part of the Gage R&R design is shown

below.

Operator 1 will test 5 parts three times each. In the figure above, you can see that

Operator 1 has tested Part 1 three times. What are the sources of variation in

these three trials? It is the measurement equipment itself. The operator is the same

and the part is the same. The variation in these three trials is a measure of the

repeatability. It is also called the equipment variation in Gage R&R studies or the

"within" variation in ANOVA studies.

Operator 1 also runs Parts 2 through 5 three times each. The variation in those

results includes the variation due to the parts as well as the equipment variation.

Operator 2 and 3 also test the same 5 parts three times each. The variation in all

results includes the equipment variation, the part variation, the operator variation

and the interaction between operators and parts. The variation in all results is the

reproducibility.

The data from the December 2007 newsletter are shown in the table below.

Operator Part Results

A 1 3.29 3.41 3.64

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2 2.44 2.32 2.42

3 4.34 4.17 4.27

4 3.47 3.5 3.64

5 2.2 2.08 2.16

B

1 3.08 3.25 3.072 2.53 1.78 2.32

3 4.19 3.94 4.34

4 3.01 4.03 3.2

5 2.44 1.8 1.72

C

1 3.04 2.89 2.85

2 1.62 1.87 2.04

3 3.88 4.09 3.67

4 3.14 3.2 3.11

5 1.54 1.93 1.55The operator is listed in first column and the part numbers in the second column.

The next three columns contain the results of the three trials for that operator and

part number. For example, the three trial results for Operator A and Part 1 are

3.29, 3.41 and 3.64.

We will now take a look at the ANOVA table, which is used as a starting point for

analyzing the results.

The ANOVA Table for Gage R&R

In most cases, you will use computer software to do the calculations. Since this is a

relatively simple Gage R&R, we will show how the calculations are done. This

helps understand the process better. The software usually displays the results in

an ANOVA table. The basic ANOVA table is shown in the table below for the

following:

k = number of appraisers

r = number of replications

n= number of parts

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The first column is the source of variability. Remember that a Gage R&R study is a

study of variation. There are five sources of variability in this ANOVA approach: the

operator, the part, the interaction between the operator and part, the equipment

and the total.

The second column is the degrees of freedom associated with the source of

variation. The degrees of freedom are simply the number of values of a statistic

that are free to vary. For example, suppose you have a sample that contains n

observations. We use the sample to estimate something - usually an average.

When we want to estimate something, it costs us one degree of freedom. So, if we

have n observations and want to estimate the average, then we have n - 1 degrees

of freedom left.

The third column is the sum of squares (SS) associated with the source of

variation. The sum of squares is a measure of variation. It measures the squared

deviations around an average. Remember what the equation for the variance is?

The variance of a set of number is given by:

The sum of squares for the source of variation is very similar to the numerator. You

just take the sum of squares around different averages depending on the source ofvariation.

The fourth column is the mean square associated with the source of variation. The

mean square is the estimate of the variance for that source of variability based on

the amount of data we have (the degrees of freedom). So, the mean square is the

sum of squares divided by the degrees of freedom. Note the similarity to the

formula for the variance above.

The fifth column is the F value. This isthe statistic that is calculated to

determine if 43.01 4.03 3.2

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4 3.14 3.2 3.11

5 2.2 2.08 2.16 1.9356 1.0165

5 2.44 1.8 1.72

5 1.54 1.93 1.55

Sum ofDeviations 3.2122

9(Sum ofDeviations)

28.9094

Thus,

SSP= 28.9094

Again, you can see how the sum of square due to parts is based on how the part

averages deviate from the overall average. There are five parts. Again, we

calculated the overall average, so one degree of freedom is lost. There are n - 1 =

5 -1 = 4 degrees of freedom associated with the parts sum of squares.

Equipment (Within) Sum of Square and Degrees of Freedom

The equipment sum of squares uses the deviation of the three trials for a given part

and a given operator from the average for that part and operator. This can be

expressed as:

The calculations are shown in the table below.

OperatorPartsTrial

1Trial

2Trial

3

Averageof 3

Trials

Squared

Deviation

Trial 1

SquaredDeviation

Trial 2

SquaredDeviation

Trial 3

A

1 3.29 3.41 3.64 3.447 0.025 0.001 0.037

2 2.44 2.32 2.42 2.393 0.002 0.005 0.001

3 4.34 4.17 4.27 4.260 0.006 0.008 0.000

4 3.47 3.5 3.64 3.537 0.004 0.001 0.011

5 2.2 2.08 2.16 2.147 0.003 0.004 0.000

B

1 3.08 3.25 3.07 3.133 0.003 0.014 0.0042 2.53 1.78 2.32 2.210 0.102 0.185 0.012

3 4.19 3.94 4.34 4.157 0.001 0.047 0.034

4 3.01 4.03 3.2 3.413 0.163 0.380 0.046

5 2.44 1.8 1.72 1.987 0.206 0.035 0.071

C

1 3.04 2.89 2.85 2.927 0.013 0.001 0.006

2 1.62 1.87 2.04 1.843 0.050 0.001 0.039

3 3.88 4.09 3.67 3.880 0.000 0.044 0.044

4 3.14 3.2 3.11 3.150 0.000 0.003 0.002

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5 1.54 1.93 1.55 1.673 0.018 0.066 0.015

Sum 1.712

Thus,

SSE= 1.712

Again, note that the sum of squares is examining variation around an average. Forthe within variation, it is the variation in the three trials around the average of those

three trials.

We calculated an average for each set of three trials. So, we lost one degree of

freedom for each set of three trials or r - 1. There were nk set of three trials, so the

degrees of freedom associated with the equipment variation is nk(r-1) = 30.

The variability chart below shows the results by part by operator.

Interaction Sum of Square and Degrees of Freedom

We will make use of the equality stated earlier to find the interaction sum of

squares. This equality was:

SST= SS0+ SSP+ SS0*P+ SSE

SS0*P= SST- (SS0+ SSP+ SSE)

SS0*P= 32.317 - (1.63 + 28.909 + 1.712)

SS0*P= 0.065

The same equality holds for the degrees of freedom:

df0*P= dfT - (df0+ dfP+ dfE)

df0*P=44 - (2 + 4 + 30)

df0*P= 8

Summary

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This is the first of a multi-part series on using ANOVA to analyze a Gage R&R

study. It focused on providing a detailed explanation of how the calculations are

done for the sum of squares and degrees of freedom. We will finish out the ANOVA

table as well as complete the Gage R&R calculations in the coming issues.

Quick Links

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Ordering Information

September 2012

This month's newsletter is the second in a multi-part series on

using the ANOVA method for a Gage R&R study. This method simply uses

analysis of variance to analyze the results of a gage R&R study instead of the

classical average and range method. The two methods do not generate the same

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results, but they will (in most cases) be similar. With the ANOVA method, we will

break down the variance into four components: parts, operators, interaction

between parts and operators and the repeatability error due to the measurement

system (or gage) itself.

Thefirst part of this seriesfocused on part of the ANOVA table. We took an in-depth look at how the sum of squares and degrees of freedom were determined.

Many people do not understand how the calculations work and the information that

is contained in the sum of squares and the degrees of freedom. In this issue we will

complete the ANOVA table and show how to determine the % of total variance that

is due to the measurement system (the % GRR).

In this issue:

The Data

The ANOVA Table for Gage R&R

The ANOVA Table Results

Expected Mean Squares

The Variances of the Components

The % Gage R&R

Summary

Quick Links

As always, please feel free to leave a comment at the bottom newsletter.

The Data

We are using the data from ourDecember 2007 newsletteron the average and

range method for Gage R&R. This newsletter also explains how to set up a gage

R&R study. In this example, there were three operators who tested five parts three

times. A partial picture of the Gage R&R design is shown below.

Operator 1 tested each 5 parts three times. In the figure above, you can see that

Operator 1 has tested Part 1 three times. What are the sources of variation in

these three trials? It is the measurement equipment itself. The operator is the same

and the part is the same. The variation in these three trials is a measure of the

repeatability. It is also called the equipment variationin Gage R&R studies or

just with the within variationin ANOVA studies.

Operator 1 also runs Parts 2 through 5 three times each. The variation in those

results includes the variation due to the parts as well as the equipment variation.

http://www.spcforexcel.com/anova-gage-rr-part-1http://www.spcforexcel.com/anova-gage-rr-part-1http://www.spcforexcel.com/anova-gage-rr-part-1http://www.spcforexcel.com/anova-gage-rr-part-2#the_datahttp://www.spcforexcel.com/anova-gage-rr-part-2#the_datahttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_for_Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_for_Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_Resultshttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_Resultshttp://www.spcforexcel.com/anova-gage-rr-part-2#Expected_Mean_Squareshttp://www.spcforexcel.com/anova-gage-rr-part-2#Expected_Mean_Squareshttp://www.spcforexcel.com/anova-gage-rr-part-2#Variance_of_Componentshttp://www.spcforexcel.com/anova-gage-rr-part-2#Variance_of_Componentshttp://www.spcforexcel.com/anova-gage-rr-part-2#Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#Summaryhttp://www.spcforexcel.com/anova-gage-rr-part-2#Summaryhttp://www.spcforexcel.com/anova-gage-rr-part-2#Quick_Linkshttp://www.spcforexcel.com/anova-gage-rr-part-2#Quick_Linkshttp://www.spcforexcel.com/variable-measurement-systems-part-4-gage-rrhttp://www.spcforexcel.com/variable-measurement-systems-part-4-gage-rrhttp://www.spcforexcel.com/variable-measurement-systems-part-4-gage-rrhttp://www.spcforexcel.com/variable-measurement-systems-part-4-gage-rrhttp://www.spcforexcel.com/anova-gage-rr-part-2#Quick_Linkshttp://www.spcforexcel.com/anova-gage-rr-part-2#Summaryhttp://www.spcforexcel.com/anova-gage-rr-part-2#Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#Variance_of_Componentshttp://www.spcforexcel.com/anova-gage-rr-part-2#Expected_Mean_Squareshttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_Resultshttp://www.spcforexcel.com/anova-gage-rr-part-2#ANOVA_Table_for_Gage_RRhttp://www.spcforexcel.com/anova-gage-rr-part-2#the_datahttp://www.spcforexcel.com/anova-gage-rr-part-1

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Operator 2 and 3 also test the same 5 parts three times each. The variation in all

results includes the equipment variation, the part variation, the operator variation

and the interaction between operators and parts. An interaction can exist if the

operator and parts are not independent. The variation due to operators is called the

reproducibility. The data we are using are shown in the table below.

Operator Part Results

A

1 3.29 3.41 3.64

2 2.44 2.32 2.42

3 4.34 4.17 4.27

4 3.47 3.5 3.64

5 2.2 2.08 2.16

B

1 3.08 3.25 3.072 2.53 1.78 2.32

3 4.19 3.94 4.34

4 3.01 4.03 3.2

5 2.44 1.8 1.72

C

1 3.04 2.89 2.85

2 1.62 1.87 2.04

3 3.88 4.09 3.67

4 3.14 3.2 3.11

5 1.54 1.93 1.55

The ANOVA Table for Gage R&R

In most cases, you will use computer software to do the calculations. Since this is a

relatively simple Gage R&R, we will show how the calculations are done. This

helps understand the process better. The software usually displays the results in

an ANOVA table. The basic ANOVA table is shown in the table below for the

following where k = number of operators, r = number of replications, and n=

number of parts.

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The first column is the source of variability. Remember that a Gage R&R study is a

study of variation. There are five sources of variability in this ANOVA approach: the

operator, the part, the interaction between the operator and part, the equipment

and the total.

The second column is the degrees of freedom associated with the source of

variation. The third column is the sum of squares. The calculations with these two

columns were covered in thefirst part of this series.

The fourth column is the mean square associated with the source of variation. The

mean square is the estimate of the variance for that source of variability (not

necessarily by itself) based on the amount of data we have (the degrees of

freedom). So, the mean square is the sum of squares divided by the degrees of

freedom. We wi l l use the mean squ are informat ion to est imate the var iance of

each source of var iat ion this is the key to analyzing the Gage R&R resul ts.

The fifth column is the F value. This is the statistic that is calculated to determine if

the source of variability is statistically significant. It is based on the ratio of two

variances (or mean squares in this case).

The ANOVA Table Results

The data was analyzed using the SPC for Excel software. The results for theANOVA table are shown below.

Source df SS MS F p Value

Operator 2 1.630 0.815 100.322 0.0000

Part 4 28.909 7.227 889.458 0.0000

Operator by Part 8 0.065 0.008 0.142 0.9964

Equipment 30 1.712 0.057

Total 44 32.317

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Note that there is an additional column in this outputthe p values. This is the

column we want to examine first. If the p value is less than 0.05, it means that the

source of variation has a significant impact on the results. As you can see in the

table, the operator by part source is not significant. Its p value is 0.9964. Many

software packages contain an option to remove the interaction if the p value isabove a certain valuemost often 0.25. In that case, the interaction is rolled into

the equipment variation. We will keep it in the calculations herethough it has little

impact since its mean square is so small.

The next column we want to look at is the mean square column. This column is an

estimate of the variance due to the source of variation. So,

MSOperators= 0.815

MSParts= 7.227

MSOperators*Parts= 0.008

MSEquipment= 0.057You might be tempted to assume, for example, that the variance due to the

operators is 0.815. However, this would be wrong. There are other sources of

variation present in all put one of these variances. We must use the Expected

Mean Square to find out what other sources of variation are present. We will use 2

to denote a variance due to a single source.

Expected Mean Squares

As stated above, the mean square column contains a variance that is related to the

source of variation in the first column. To find the variance of each source ofvariation, we have to use the expected mean square (EMS). The expected mean

square represents the variance that the mean square column is estimating.

There are algorithms that allow you to generate the expected mean squares. This

is beyond the scope of this newsletter. So, we will just present the expected mean

squares.

Lets start at the bottom with the equipment variation. This is really the within

variation (also called error). It is the repeatability portion of the Gage R&R study.

The expected mean square for equipment is the repeatability variance. The

repeatability variance is the mean square of the equipment from the ANOVA table.

Now consider the interaction expected mean square which is given by:

Note that the EMS for the interaction tern contains the repeatability variance as

well as the variance of the interaction between the operators and parts. This is

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what is estimated by the mean square of the interaction. The parts expected mean

square is shown below.

Note that the EMS for parts contains the variances for repeatability, the interactionand parts. This is what is estimated by the mean square for parts. And last, the

expected mean square for the operators is given by:

The EMS for operators contains the variances for repeatability, the interaction and

operators. This is what the mean square for operators is estimating.

The Variances of the Components

We can solve the above equations for each individual 2. Repeatability is already

related directly to the mean square for equipment so we dont need to do anything

there. The other three can be solved as follows:

We can now do the calculations to estimate each of the variances.

Note that the value of the variance for the interaction between the operators and

parts is actually negative. If this happens, the variance is simply set to zero.

% Gage R&R

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The Measurement Systems Analysis manual published by AIAG (www.aiag.org)

provides the following definition: The measurement system variation for

repeatability and reproducibility (or GRR) is defined as the following:

GRR2=EV

2+ AV

2

where EV is the equipment variance and AV is the appraiser (or operator)variance. Thus:

The total variance is the sum of the components:

We can use the total variance to determine the % contribution of each source to

the total variance. This is done by dividing the variance for each source by the total

variance. For example, the % variation due to GRR is given by:

The results for all the sources of variation are shown in the table below.

Source Variance% ofTotalVariance

GRR 0.1109 12.14%

Equipment(Repeatability)

0.0571 6.25%

Operators(Reproducibility)

0.0538 5.89%

Interaction 0.0000 0.00%

Parts 0.8021 87.86%

Total 0.9130 100.00%

Based on this analysis, the measurement system is responsibility for 12.14% of the

total variance. This may or may not be acceptable depending on the process and

what your customer needs and wants. Note that this result is based on the total

variance. It is very important that the parts you use in the Gage R&R study

represent the range of values you will get from production.One of the major problems people have with Gage R&R studies is selecting

samples that do not truly reflect the range of production. If you have to do that, you

can begin to look at how the results compare to specifications. We will take a look

at that next month as we compare the ANOVA method to the Average and Range

method for analyzing a Gage R&R experiment. You could also use a variance

calculated directly from a month's worth of production in place of the total variance

in the analysis.

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Summary

In this newsletter, we continued our exploration of the using ANOVA to analyze a

Gage R&R experiment. We completed the ANOVA table, presented the expected

mean squares and how to use those to estimate the variances of the components,

and showed how to determine the %GRR as a percent of the total variance.In the next newsletter, we will compare the ANOVA method to the Average and

Range method for Gage R&R.

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