# Using Fourier Transform to get frequency and phase

Suppose I have samples of a periodic function, what is a good way to get frequency and phase information out of it?

In particular, I'd like to get a form like

``````a+b Cos[c x + d]
``````

Here's a part of the sample

``````{255,255,255,249,64,0,0,0,0,0,0,0,0,0,0,0,0,233,255,255,255,255,255,255,255,255,255,209,0,0,0,0,0,0,0,0,0,0,0,0,118,255,255,255,255,255,255,255,255,255,255,132,0,0,0,0,0,0,0,0,0,0,0,0,200,255,255,255,255,255,255,255,255,255,239,19,0,0,0,0,0,0,0,0,0,0,0,46,245,255,255,255,255,255,255,255,255,255,186,0}
``````
-
Nice to see you again! WRT your Q: Why do you want to fit a `Cos[ ]` there? –  belisarius Jul 12 '11 at 3:07
Well, just trying to figure out how to get the phase of the signal. It comes out of calibration picture in book scanning –  Yaroslav Bulatov Jul 12 '11 at 5:42
For the frequency you could do an autocorrelation, and then detect maxima and minima. The autocorrelation works better if you trim your your points at both edges. –  belisarius Jul 12 '11 at 6:23

## Using Autocorrelation and FindFit[ ]

``````(*Your list*)
ListPlot@l
``````

``````(*trim the list*)
l1 = Drop[l, (First@Position[l, 0])[[1]] - 1];
l2 = Drop[l1, Length@l1 - (Last@Position[l1, 0])[[1]] - 1];
(*autocorrelate*)
ListLinePlot@(ac = ListConvolve[l2, l2, {1, 1}])
``````

``````(*Find Period by taking means of maxs and mins spacings*)
period = Mean@
Join[
Differences@(maxs = Table[If[ac[[i - 1]] < ac[[i]] > ac[[i + 1]], i,
Sequence @@ {}], {i, 2, Length@ac - 1}]),
Differences@(mins = Table[If[ac[[i - 1]] > ac[[i]] < ac[[i + 1]], i,
Sequence @@ {}], {i, 2, Length@ac - 1}])];

(*Show it*)
Show[ListLinePlot[(ac = ListConvolve[l2, l2, {1, 1}]),
Epilog ->
Inset[Framed[Style["Mean Period = " <> ToString@N@period, 20],
Background -> LightYellow]]],
Sequence @@@ Arrow[{{{#[[1]], Min@ac}, {#[[2]], Min@ac}}}] & /@
Partition[mins, 2, 1], {Blue},
Sequence @@@ Arrow[{{{#[[1]], Max@ac}, {#[[2]], Max@ac}}}] & /@
Partition[maxs, 2, 1]]]]
``````

``````(*Now let's fit the Cos[ ] to find the phase*)
model = a + b Cos[x (2 Pi)/period + phase];
ff = FindFit[l, model, {a, b, phase}, x,
Method -> NMinimize, MaxIterations -> 100];

(*Show results*)
Show[ListPlot[l, PlotRange -> All,
Epilog ->
Inset[Framed[Style["Phase = " <> ToString@N@(phase /. ff), 20],
Background -> LightYellow]]], Plot[model /. ff, {x, 1, 100}]]
``````

-
Thanks! It's good to get refreshed on the techniques –  Yaroslav Bulatov Jul 14 '11 at 6:09
@Yaro the non-trivial thing is that you can't fit the trig function at once, you need to find the frequency first. I don't remember exactly why, but it happened to me before and found this two steps procedure far better –  belisarius Jul 14 '11 at 12:43
Please look at `FourierDCT` ref page.
Your data looks very much like `SquareWave` function. By manual inspection it seems like your data fit `SquareWave[{0, 255}, (x + 5)/23 ]`.