Here is an interactive version, you can click on a point and then corresponding density plot appears. Mainly used `?identify`

and as @Tyler suggested `?zoomInPlot`

.

Some more details on how it works: `rxlim`

and `rylim`

defined at the very beginning is the size of rectangle which surrounds the selected point, so one might want to change the factor `/20`

. Possibility of multiple clicks is nontrivial: `identify()`

detects clicks only in the "recent" plot, i.e.

```
par(mfrow = c(1,2))
plot(1:10) # 1
plot(1:10) # 2
identifyPch(1:10)
```

detects clicks only in the plot #2 (here `identifyPch()`

is from `?identify`

). For this issue `par(mfg=c(1, 1))`

was used:

mfg

A numerical vector of the form c(i, j) where i and j indicate
which figure in an array of figures is to be drawn next (if setting)
or is being drawn (if enquiring). The array must already have been set
by mfcol or mfrow.

```
zoom <- function (x, y, xlim, ylim, xd, yd)
{
rxlim <- x + c(-1, 1) * (diff(range(xd))/20)
rylim <- y + c(-1, 1) * (diff(range(yd))/20)
par(mfrow = c(1, 2))
plot(xd, yd, xlab = "mean", ylab = "sd")
xext <- yext <- rxext <- ryext <- 0
if (par("xaxs") == "r") {
xext <- diff(xlim) * 0.04
rxext <- diff(rxlim) * 0.04
}
if (par("yaxs") == "r") {
yext <- diff(ylim) * 0.04
ryext <- diff(rylim) * 0.04
}
rect(rxlim[1] - rxext, rylim[1] - ryext, rxlim[2] + rxext,
rylim[2] + ryext)
xylim <- par("usr")
xypin <- par("pin")
rxi0 <- xypin[1] * (xylim[2] - (rxlim[1] - rxext))/diff(xylim[1:2])
rxi1 <- xypin[1] * (xylim[2] - (rxlim[2] + rxext))/diff(xylim[1:2])
y01i <- xypin[2] * (xylim[4] - (rylim[2] + ryext))/diff(xylim[3:4])
y02i <- xypin[2] * ((rylim[1] - ryext) - xylim[3])/diff(xylim[3:4])
mu <- x
curve(dnorm(x, mean = mu, sd = y), from = -4 * y + mu, to = 4 * y + mu,
xlab = paste("mean:", round(mu, 2), ", sd: ", round(y, 2)), ylab = "")
xypin <- par("pin")
par(xpd = NA)
xylim <- par("usr")
xymai <- par("mai")
x0 <- xylim[1] - diff(xylim[1:2]) * (xymai[2] + xymai[4] +
rxi0)/xypin[1]
x1 <- xylim[1] - diff(xylim[1:2]) * (xymai[2] + xymai[4] +
rxi1)/xypin[1]
y01 <- xylim[4] - diff(xylim[3:4]) * y01i/xypin[2]
y02 <- xylim[3] + diff(xylim[3:4]) * y02i/xypin[2]
par(xpd = TRUE)
xend <- xylim[1] - diff(xylim[1:2]) * xymai[2]/(2 * xypin[1])
xprop0 <- (xylim[1] - xend)/(xylim[1] - x0)
xprop1 <- (xylim[2] - xend)/(xylim[2] - x1)
par(xpd = NA)
segments(c(x0, x0, x1, x1),
c(y01, y02, y01, y02),
c(xend, xend, xend, xend),
c(xylim[4] - (xylim[4] - y01) * xprop0,
xylim[3] + (y02 - xylim[3]) * xprop0,
xylim[4] - (xylim[4] - y01) * xprop1,
xylim[3] + (y02 - xylim[3]) * xprop1))
par(mfg = c(1, 1))
plot(xd, yd, xlab = "mean", ylab = "sd")
}
ident <- function(x, y, ...)
{
ans <- identify(x, y, n = 1, plot = FALSE, ...)
if(length(ans)) {
zoom(x[ans], y[ans], range(x), range(y), x, y)
points(x[ans], y[ans], pch = 19)
ident(x, y)
}
}
x <- rnorm(10)
y <- rnorm(10, mean = 5)
par(mfrow = c(1, 2))
plot(x, y, xlab = "mean", ylab = "sd")
ident(x, y)
```

`plotrix`

package has a`zoomInPlot`

function though your question doesn't appear to be answered by this function, the source code may be useful.`zoomInPlot`

, because the "zoomed" plot is not a part of the original plot, it's generated according to the point I select (or a fixed point, if I cannot make an interactive version)`zoomInPlot`

plot is actually two different plots made to look like a zoom. You'll have to tear apart the`zoomInPlot`

code and can create the plot you're after. As far as interactive this will require even more digging.1more comment