I can think of a couple of ways of going about this with `lattice`

. You could either use `xyplot`

and fill panels with `panel.fill`

, or you can use `levelplot`

. The polygons themselves have to be added with a custom panel and `lpolygon`

. Here's how I've done it with `levelplot`

. I'm really a `lattice`

novice, though, and there may very well be some shortcuts that I don't know about.

Because I'm using `levelplot`

, we first create a matrix containing median `MathAch`

scores for each combination of `MEANSES`

and `SES`

. These will be used to plot the cell colours.

```
library(lattice)
library(nlme)
data(MathAchieve)
```

Below, I convert `SES`

and `MEANSES`

into factors using `cut`

, with breakpoints as in the Wikipedia example.

```
MathAchieve$SESfac <- as.numeric(cut(MathAchieve$SES, seq(-2.5, 2, 0.5)))
MathAchieve$MEANSESfac <- as.numeric(cut(MathAchieve$MEANSES,
seq(-1.25, 1, 0.25)))
```

I'm not sure how to plot the four panels as on the Wikipedia page, so I'll just subset to non-minority females:

```
d <- subset(MathAchieve, Sex=='Female' & Minority=='No')
```

To convert this dataframe to a matrix, I `split`

it to a list and then coerce back to a matrix with the appropriate dimensions. Each cell of the matrix contains the median `MathAch`

for a particular combination of `SESfac`

and `MEANSESfac`

.

```
l <- split(d$MathAch, list(d$SESfac, d$MEANSESfac))
m.median <- matrix(sapply(l, median), ncol=9)
```

When we use `levelplot`

we will have access to `x`

and `y`

, being the coordinates of the "current" cell. In order to pass the vector of `MathAch`

to `levelplot`

, so that a polygon can be plotted for each cell, I create a matrix (same dimensions as `m.median`

) of lists, where each cell is a list containing a `MathAch`

vector.

```
m <- matrix(l, ncol=9)
```

Below we create a color ramp as used by Wolfram Fischer in the example on Wikipedia.

```
colramp <- colorRampPalette(c('#fff495', '#bbffaa', '#70ffeb', '#72aaff',
'#bf80ff'))
```

Now we define the custom panel function. I've commented throughout to explain:

```
fanplot <- function(x, y, z, subscripts, fans, ymin, ymax,
nmax=max(sapply(fans, length)), ...) {
# nmax is the maximum sample size across all combinations of conditioning
# variables. For generality, ymin and ymax are limits of the circle around
# around which fancharts are plotted.
# fans is our matrix of lists, which are used to plot polygons.
get.coords <- function(a, d, x0, y0) {
a <- ifelse(a <= 90, 90 - a, 450 - a)
data.frame(x = x0 + d * cos(a / 180 * pi),
y = y0 + d * sin(a / 180 * pi))
}
# getcoords returns coordinates of one or more points, given angle(s),
# (i.e., a), distances (i.e., d), and an origin (x0 and y0).
panel.levelplot(x, y, z, subscripts, ...)
# Below, we scale the raw vectors of data such that ymin thru ymax map to
# 0 thru 360. We then calculate the relevant quantiles (i.e. 25%, 50% and 75%).
smry <- lapply(fans, function(y) {
y.scld <- (y - ymin)/(ymax - ymin) * 360
quantile(y.scld, c(0.25, 0.5, 0.75)) - 90
})
# Now we use get.coords to determine relevant coordinates for plotting
# polygons and lines. We plot a white line inwards from the circle's edge,
# with length according to the ratio of the sample size to nmax.
mapply(function(x, y, smry, n) {
if(!any(is.na(smry))) {
lpolygon(rbind(c(x, y),
get.coords(seq(smry['25%'], smry['75%'], length.out=200),
0.3, x, y)), col='gray10', lwd=2)
llines(get.coords(c(smry['50%'], 180 + smry['50%']), 0.3,
x, y), col=1, lwd=3)
llines(get.coords(smry['50%'], c(0.3, (1 - n/nmax) * 0.3),
x, y), col='white', lwd=3)
}
}, x=x, y=y, smry=smry, n=sapply(fans, length))
}
```

And finally use this custom panel function within `levelplot`

:

```
levelplot(m.median, fans=m, ymin=0, ymax=28,
col.regions=colramp, at=seq(0, 25, 5), panel=fanplot,
scales=list(tck=c(1, 0),
x=list(at=seq_len(ncol(m.median) + 1) - 0.5,
labels=seq(-2.5, 2, 0.5)),
y=list(at=seq_len(nrow(m.median) + 1) - 0.5,
labels=seq(-1.25, 1, 0.25))),
xlab='Socio-economic status of students',
ylab='Mean socio-economic status for the school')
```

I haven't coloured cells grey if they have sample size < 7, as was done for the equivalent plot on the Wikipedia page, but this could be done with `lrect`

if needed.

`plotrix`

package has bunch of specialized charting functions. – BondedDust May 10 '14 at 1:00