# Testing for periodicity of noisy biological data: periodogram significance?

I'm trying to analyze some noisy time-series data in R. The data are based on the CO2 emission of animals and they show a sort of cyclic periodicity that I'd like to characterize. I'd like to test the hypotheses:

H0: There is no cyclic CO2 emission (i.e. no more than random).

H1: There is a pattern of CO2 emission in cycles or pulses.

So to do this I've imported the data into R, converted it to a time series class, and plotted its periodogram.

``````t25a <- read.table("data.txt", header=TRUE, sep="\t")
t1 <- ts(t25a\$Co2)
plot(t1)
spec.pgram(t1, spans=4, log="no")
``````

Here's what that looks like, with the raw data plotted on top and the periodogram beneath:

In the bottom figure, I can see four or five somewhat-distinct peaks indicating a frequency component in the data. My question is -- are they all equally "important"? Is there any way to test whether the observed peaks are significantly different from each other or from the predictions of the null hypothesis? All I know how to do is find the frequency associated with those peaks, but I'd like a more objective method for determining how many "significant" peaks there really are in the data.

• You understand what the units of a power spectrum are, yes? [units**2/Hz] You can think of the integrated spectrum as the variance of the original timeseries, so if a peak is larger than another, it has more energy (signal) at that frequency than the other does. So the "significance" is not really a meaningful question. And you should really be using a tapering scheme, and plotting logarithmic frequency (in this case). Commented Oct 21, 2011 at 19:25
• @AndyBarbour First, the units. My understanding is that the y-axis on the periodogram above is a measure of power and that the x-axis is the inverse frequency. Where does the *2 come from in your units*2/Hz? As a measure of relative significance of different components of the signal, might I consider the ratio of an integrated peak to the total area? Commented Oct 21, 2011 at 20:21
• Take a look at Parseval's Theorem, or work out the Fourier transform on an analytic function to easily demonstrate the units. The units on the plot are probably, for y, in dB relative to 1 unit**2/Hz, and for x, 0 to the Nyquist frequency. It depends what question you want to answer, but the peaks are likely real cycles in the data (just by inspection of your timeseries). Commented Oct 21, 2011 at 23:25
• I think reading up on the time-series literature might be a good idea (or possibly asking a variant of this question on Stack Exchange). There is a big (and alas complicated) literature on spectral analysis, with various different kinds of hypothesis testing frameworks. I personally like Diggle's time series analysis book: amazon.com/Time-Biostatistical-Introduction-Peter-Diggle/dp/… Commented Oct 22, 2011 at 14:59
• PS I strongly recommend inspecting the periodogram on the log scale -- and taking a look at the 95% confidence interval that is plotted by default by `plot.spec`. And note that @AndyBarbour is talking about squaring the units, not multiplying them by two. The ratios of integrated peaks are indeed sensible -- if you normalize correctly, they represent fractions of overall variance accounted for by various frequency ranges. For example, see math.mcmaster.ca/~bolker/bbpapers/BolkerGrenfell1995.pdf (username: "bbpapers", password "research") Commented Oct 22, 2011 at 15:04

`````` Buja, A., Cook, D. Hofmann, H., Lawrence, M. Lee, E.-K., Swayne,
The `vis.test` function in the `TeachingDemos` package for R helps with implementing this test (but there are other ways as well).