Fourier transformation quick and dirty

I tend to forget how to recover a frequency spectrum from a series of data points using the FourierSeries (read as: I forget how to compute the frequency corresponding to a specific channel in the fourier series). To stop me from forgetting I came up with the following quick and dirty module. It takes a one-dimensional list of data points that were taken over a time interval of timelength and returns a list containing pairs of {Frequency, complex amplitude}. As you can see the frequency is simply (number of data point – 1) divided by the time interval covered by the data. A quick plausibility check confirms this result: Data point 0 corresponds to the offset of the fourier series (frequency 0). The maximum observable frequency (found at position (number of data points / 2)) is (number of data points / 2) per timelength and in agreement with the Nyquist frequency.

FourierFreqs[data_, timelength_] := Module[{}, Transpose[ {((Range[Length[data]] - 1))/timelength, Fourier[data]} ] ]

Demonstration of the results of the above function returning the frequency spectrum of a sine. — A ListPlot of input data and the recovered frequency spectrum.