# Calculate within and between variances and confidence intervals in R

I need to calculate the within and between run variances from some data as part of developing a new analytical chemistry method. I also need confidence intervals from this data using the R language

I assume I need to use anova or something ?

My data is like

``````> variance
Run Rep Value
1    1   1  9.85
2    1   2  9.95
3    1   3 10.00
4    2   1  9.90
5    2   2  8.80
6    2   3  9.50
7    3   1 11.20
8    3   2 11.10
9    3   3  9.80
10   4   1  9.70
11   4   2 10.10
12   4   3 10.00
``````
-

You have four groups of three observations:

``````> run1 = c(9.85, 9.95, 10.00)
> run2 = c(9.90, 8.80, 9.50)
> run3 = c(11.20, 11.10, 9.80)
> run4 = c(9.70, 10.10, 10.00)
> runs = c(run1, run2, run3, run4)
> runs
[1]  9.85  9.95 10.00  9.90  8.80  9.50 11.20 11.10  9.80  9.70 10.10 10.00
``````

Make some labels:

``````> n = rep(3, 4)
> group = rep(1:4, n)
> group
[1] 1 1 1 2 2 2 3 3 3 4 4 4
``````

Calculate within-run stats:

``````> withinRunStats = function(x) c(sum = sum(x), mean = mean(x), var = var(x), n = length(x))
> tapply(runs, group, withinRunStats)
\$`1`
sum         mean          var            n
29.800000000  9.933333333  0.005833333  3.000000000

\$`2`
sum  mean   var     n
28.20  9.40  0.31  3.00

\$`3`
sum  mean   var     n
32.10 10.70  0.61  3.00

\$`4`
sum        mean         var           n
29.80000000  9.93333333  0.04333333  3.00000000
``````

You can do some ANOVA here:

``````> data = data.frame(y = runs, group = factor(group))
> data
y group
1   9.85     1
2   9.95     1
3  10.00     1
4   9.90     2
5   8.80     2
6   9.50     2
7  11.20     3
8  11.10     3
9   9.80     3
10  9.70     4
11 10.10     4
12 10.00     4

> fit = lm(runs ~ group, data)
> fit

Call:
lm(formula = runs ~ group, data = data)

Coefficients:
(Intercept)       group2       group3       group4
9.933e+00   -5.333e-01    7.667e-01   -2.448e-15

> anova(fit)
Analysis of Variance Table

Response: runs
Df  Sum Sq Mean Sq F value  Pr(>F)
group      3 2.57583 0.85861  3.5437 0.06769 .
Residuals  8 1.93833 0.24229
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

> degreesOfFreedom = anova(fit)[, "Df"]
> names(degreesOfFreedom) = c("treatment", "error")
> degreesOfFreedom
treatment     error
3         8
``````

Error or within-group variance:

``````> anova(fit)["Residuals", "Mean Sq"]
[1] 0.2422917
``````

Treatment or between-group variance:

``````> anova(fit)["group", "Mean Sq"]
[1] 0.8586111
``````

This should give you enough to do confidence intervals.

-

I'm going to take a crack at this when I have more time, but meanwhile, here's the `dput()` for Kiar's data structure:

``````structure(list(Run = c(1, 1, 1, 2, 2, 2, 3, 3, 3, 4, 4, 4), Rep = c(1,
2, 3, 1, 2, 3, 1, 2, 3, 1, 2, 3), Value = c(9.85, 9.95, 10, 9.9,
8.8, 9.5, 11.2, 11.1, 9.8, 9.7, 10.1, 10)), .Names = c("Run",
"Rep", "Value"), row.names = c(NA, -12L), class = "data.frame")
``````

... in case you'd like to take a quick shot at it.

-

If you want to apply a function (such as `var`) across a factor such as `Run` or `Rep`, you can use `tapply`:

``````> with(variance, tapply(Value, Run, var))
1           2           3           4
0.005833333 0.310000000 0.610000000 0.043333333
> with(variance, tapply(Value, Rep, var))
1          2          3
0.48562500 0.88729167 0.05583333
``````
-
Nice! That is Elegant Code in my opinion. –  kpierce8 Sep 10 '09 at 19:19

I've been looking at a similar problem. I've found reference to caluclating confidence intervals by Burdick and Graybill (Burdick, R. and Graybill, F. 1992, Confidence Intervals on variance components, CRC Press)

Using some code I've been trying I get these values

``````

> kiaraov = aov(Value~Run+Error(Run),data=kiar)

> summary(kiaraov)

Error: Run
Df  Sum Sq Mean Sq
Run  3 2.57583 0.85861

Error: Within
Df  Sum Sq Mean Sq F value Pr(>F)
Residuals  8 1.93833 0.24229
> confint = 95

> a = (1-(confint/100))/2

> grandmean = as.vector(kiaraov\$"(Intercept)"[[1]][1]) # Grand Mean (I think)

> within = summary(kiaraov)\$"Error: Within"[[1]]\$"Mean Sq"  # S2^2Mean Square Value for Within Run

> dfRun = summary(kiaraov)\$"Error: Run"[[1]]\$"Df"

> dfWithin = summary(kiaraov)\$"Error: Within"[[1]]\$"Df"

> Run = summary(kiaraov)\$"Error: Run"[[1]]\$"Mean Sq" # S1^2Mean Square for between Run

> between = (Run-within)/((dfWithin/(dfRun+1))+1) # (S1^2-S2^2)/J

> total = between+within

> between # Between Run Variance
[1] 0.2054398

> within # Within Run Variance
[1] 0.2422917

> total # Total Variance
[1] 0.4477315

> betweenCV = sqrt(between)/grandmean * 100 # Between Run CV%

> withinCV = sqrt(within)/grandmean * 100 # Within Run CV%

> totalCV = sqrt(total)/grandmean * 100 # Total CV%

> #within confidence intervals

> withinLCB = within/qf(1-a,8,Inf) # Within LCB

> withinUCB = within/qf(a,8,Inf) # Within UCB

> #Between Confidence Intervals

> n1 = dfRun

> n2 = dfWithin

> G1 = 1-(1/qf(1-a,n1,Inf)) # According to Burdick and Graybill this should be a

> G2 = 1-(1/qf(1-a,n2,Inf))

> H1 = (1/qf(a,n1,Inf))-1  # and this should be 1-a, but my results don't agree

> H2 = (1/qf(a,n2,Inf))-1

> G12 = ((qf(1-a,n1,n2)-1)^2-(G1^2*qf(1-a,n1,n2)^2)-(H2^2))/qf(1-a,n1,n2) # again, should be a, not 1-a

> H12 = ((1-qf(a,n1,n2))^2-H1^2*qf(a,n1,n2)^2-G2^2)/qf(a,n1,n2) # again, should be 1-a, not a

> Vu = H1^2*Run^2+G2^2*within^2+H12*Run*within

> Vl = G1^2*Run^2+H2^2*within^2+G12*within*Run

> betweenLCB = (Run-within-sqrt(Vl))/J # Betwen LCB

> betweenUCB = (Run-within+sqrt(Vu))/J # Between UCB

> #Total Confidence Intervals

> y = (Run+(J-1)*within)/J

> totalLCB = y-(sqrt(G1^2*Run^2+G2^2*(J-1)^2*within^2)/J) # Total LCB

> totalUCB = y+(sqrt(H1^2*Run^2+H2^2*(J-1)^2*within^2)/J) # Total UCB

> result = data.frame(Name=c("within", "between", "total"),CV=c(withinCV,betweenCV,totalCV),LCB=c(sqrt(withinLCB)/grandmean*100,sqrt(betweenLCB)/grandmean*100,sqrt(totalLCB)/grandmean*100),UCB=c(sqrt(withinUCB)/grandmean*100,sqrt(betweenUCB)/grandmean*100,sqrt(totalUCB)/grandmean*100))

> result
Name       CV      LCB      UCB
1  within 4.926418 3.327584  9.43789
2 between 4.536327      NaN 19.73568
3   total 6.696855 4.846030 20.42647
``````

Here the lower confidence interval for between run CV is less than zero, so reported as NaN.

I'd love to have a better way to do this. If I get time I might try to create a function to do this.

Paul.

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That seems just what I wanted. I'll try to find that literarue reference. –  PaulHurleyuk Sep 11 '09 at 7:47