# Plot density of periodic function

I've got a vector that represents the times (in seconds past midnight) that a bunch of events happened, and I want to plot the density of those events through the day. Here's one way to do that:

``````rs <- 60*60*24*c(rbeta(5000, 2, 5), runif(10000, 0, 1))
den <- density(rs, cut=0)
plot(den, ylim=range(0,den\$y))
``````

The problem with that is that it gets the endpoint density wrong, because this is a cyclical function. If you plot 3 periods in a row you see the true densities in the middle period:

``````den <- density(c(rs, rs+60*60*24, rs+2*60*60*24), cut=0)
plot(den, ylim=range(0,den\$y))
``````

My question is whether there's some [better] way to get the density of that middle chunk from the original data, without tripling the number of observations as I've done. I'd of course need to supply the length of the period, in case there aren't any observations near the endpoints.

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You might take a look at the `circular` package: cran.r-project.org/web/packages/circular in order to estimate the density on a circle (i.e. cyclical) data set. –  Iterator Sep 30 '11 at 15:54
Here is a blog post, Circular or spherical data, and density estimation that goes into great detail and gives extensive R code for both the calculation and graphics. I don't think they are the same functions @Iterator mentions (thanks for that reference by the way), but it should still be applicable for the plots even if you decide to use that library. –  Andy W Sep 30 '11 at 16:54
Very nice, thanks! –  Ken Williams Oct 1 '11 at 2:17

I don't think your evidence that the curve should look line a portion of the repeated spline fit is compelling. You should examine the results of hist() on the same object where you specify breaks at hour boundaries. The logspline function allows calculation of density estimates with specified bounds on hte data:

``````hist( c(c(rs, rs+60*60*24, rs+2*60*60*24), breaks= 24*3 )
require(logspline)
?logspline
fit <- logspline(c(rs), lbound=0, ubound=60*60*24)
plot(fit)
``````

A better fit because it correctly captures the fact that the end-of-the-day density is lower than the first of the day which isn't really correctly captured with that triple day densityplot.

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With the synthetic data I posted, it's true that end-of-day and start-of-day aren't the same density. But my actual day is more like "at what time of day do people brush their teeth?", so it should be smooth across the transition boundary. –  Ken Williams Oct 5 '11 at 15:56