# How to resample/rebin a spectrum?

In Matlab, I frequently compute power spectra using Welch's method (`pwelch`), which I then display on a log-log plot. The frequencies estimated by `pwelch` are equally spaced, yet logarithmically spaced points would be more appropriate for the log-log plot. In particular, when saving the plot to a PDF file, this results in a huge file size because of the excess of points at high frequency.

What is an effective scheme to resample (rebin) the spectrum, from linearly spaced frequencies to log-spaced frequencies? Or, what is a way to include high-resolution spectra in PDF files without generating excessively large files sizes?

The obvious thing to do is to simply use `interp1`:

``````  rate = 16384; %# sample rate (samples/sec)
nfft = 16384; %# number of points in the fft

[Pxx, f] =  pwelch(detrend(data), hanning(nfft), nfft/2, nfft, rate);

f2 = logspace(log10(f(2)), log10(f(end)), 300);
Pxx2 = interp1(f, Pxx, f2);

loglog(f2, sqrt(Pxx2));
``````

However, this is undesirable because it does not conserve power in the spectrum. For example, if there is a big spectral line between two of the new frequency bins, it will simply be excluded from the resulting log-sampled spectrum.

To fix this, we can instead interpolate the integral of the power spectrum:

``````  df = f(2) - f(1);
intPxx = cumsum(Pxx) * df;                     % integrate
intPxx2 = interp1(f, intPxx, f2);              % interpolate
Pxx2 = diff([0 intPxx2]) ./ diff([0 F]);       % difference
``````

This is cute and mostly works, but the bin centers aren't quite right, and it doesn't intelligently handle the low-frequency region, where the frequency grid may become more finely sampled.

Other ideas:

• write a function that determines the new frequency binning and then uses `accumarray` to do the rebinning.
• Apply a smoothing filter to the spectrum before doing interpolation. Problem: the smoothing kernel size would have to be adaptive to the desired logarithmic smoothing.
• The `pwelch` function accepts a frequency-vector argument `f`, in which case it computes the PSD at the desired frequencies using the Goetzel algorithm. Maybe just calling `pwelch` with a log-spaced frequency vector in the first place would be adequate. (Is this more or less efficient?)
• For the PDF file-size problem: include a bitmap image of the spectrum (seems kludgy--I want nice vector graphics!);
• or perhaps display a region (polygon/confidence interval) instead of simply a segmented line to indicate the spectrum.