So, since you do not precise what a Youden plot is, for you, and that I never heard of such a plot before, i'll use W. J. Youden (1959) definition directly to draw it.

The graph is prepared by drawing the customary x-axis at the bottom of the paper and laying off on this axis a scale that covers the range of results for material A. At the left the y-axis is provided with a scale in the same units that includes the range of results reported for material B. The pair of results reported by a laboratory are then used to plot a point. There will be as many points as there are reporting laboratories. After the points are plotted a horizontal median line is drawn parallel to the x-axis so that there are as many points above the line as there are below it. A second median line is drawn parallel to the y-axis and so placed that there are as many points on the left as there are on the right of this line.

Let's start with that.

```
dat <- read.table("dat_youd.csv",sep=",",head=TRUE)
datL <- split(dat,dat$levels)
#I don't really get what your levels are and why there are three of them though, but i'll assume there are equivalent to Youden's "materials".
plot(datL[[1]]$MeanValues,datL[[2]]$MeanValues,asp=1, pch=19, xlab="Sample A", ylab="Sample B")
#asp=1 because of the circle.
mB <- median(datL[[2]]$MeanValues)
mA <- median(datL[[1]]$MeanValues)
abline(h=mB, v=mA)
```

The third element of the plot is the 45° line:

Assuming that the two materials are similar in type and nearly equal in magnitude for the property the dispersion among the results reported for A should be about the same as the dispersion of the B results. In that event the 45 degree line through the intersection of the medians makes possible an estimate of the precision of the data.

Which is:

```
curve(x-(mA-mB),from=par('usr')[1],to=par('usr')[3],add=TRUE)
#I use here par('usr') so that it expands on the whole plot area
```

Then the "standard deviation" computation:

The perpendicular distance from each point to the 45 degree line can be used to form an estimate of the precision. [...] These perpendiculars need not be measured on the graph paper. Instead write for each laboratory the difference A - B keeping track of the signs. Call these differences d1, d2, ..., dn. Calculate d the algebraic average difference. Subtract d from each difference and obtain a set of corrected differences d'1, d'2,..., d'n. The average of the absolute values of these differences multiplied by sqrt(pi)/2 or 0.886 gives an estimate of standard deviation.

Let's calculate that:

```
d <- mean(datL[[1]]$MeanValues-datL[[2]]$MeanValues)
d_prime <- datL[[1]]$MeanValues-datL[[2]]$MeanValues-d
r <- mean(abs(d_prime))*sqrt(pi)/2
```

And finally the circle:

Multiplying the standard deviation obtained above by 2.45 gives the radius of the circle that should include 95 percent of the laboratories if individual constant errors could be eliminated.

That we can draw the following way:

```
r <- 2.45 * r
t <- seq(0,2*pi,by=0.01)
x <- r*cos(t) + mA
y <- r*sin(t) + mB
lines(x,y)
```

The result:

And as a function:

```
youden <- function(serieA, serieB){
plot(serieA,serieB,asp=1, pch=19, xlab="Sample A", ylab="Sample B")
mB <- median(serieB)
mA <- median(serieA)
abline(h=mB, v=mA)
curve(x-(mA-mB),from=par('usr')[1],to=par('usr')[3],add=TRUE)
d <- mean(serieA-serieB)
d_prime <- serieA-serieB-d
r <- 2.45*mean(abs(d_prime))*sqrt(pi)/2
t<-seq(0,2*pi,by=0.01)
x<-r*cos(t)+mA
y<-r*sin(t)+mB
lines(x,y)
}
```

Using your third serie as example:

```
youden(datL[[1]]$MeanValues, datL[[3]]$MeanValues)
```