FFT and decibel scales

If I take audio data on an iPhone (i.e. real) data, perform an FFT and then take the magnitudes (Re^2 + Im^2).

These vary from >0 to some large numbers, so I do `10log(n)` to get it in dB.

This gives me outputs that are negative (for the inputs that were < 1) to positive.

But the examples I've seen for this (and also drawing the spectrum in Sonic Visualiser) always have positive spectrums when measured in dB.

So what have I missed?!

On a wider note, as I understand it decibels are a ratio, so in this context when turning the FFT magnitudes into dB, what are they a ratio to?

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possible duplicate: stackoverflow.com/questions/2445756/… –  Robert Harvey Feb 14 at 18:13
In short, you're right; it is a ratio. You have to establish a "reference level," as described in the Wikipedia article. For example, with Compact Disks, zero db is considered the highest possible magnitude, so all other values are going to be negative, down to about -92 db. –  Robert Harvey Feb 14 at 18:15
It's not a dupe of stackoverflow.com/questions/2445756/ , I'm specifically asking about the outputs from FFT bins. That is a general question measuring sound levels with microphones. –  Mark Feb 14 at 18:17
OK, but the principle is the same; the answers provided there explain how to establish a "reference level." –  Robert Harvey Feb 14 at 18:18
I read the wikipedia article on this as well, which says the reference level for audio is defined a 1dB = 20 micro pascals. So presumably for audio you would go `10log(20/val)` where val is ones measurement in pascals? I can't find anywhere what is the reference level for FFTs, or why I get a mix of negative & positive numbers when other sources always have spectrums as positive. There's probably a really simple answer I've just missed! –  Mark Feb 14 at 18:21
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The simple answer is that, for the most part, you can add an arbitrary number to the dB value to make the values all positive, or all negative, or whatever you prefer. With an uncalibrated microphone, like on the iPhone, this is all that makes sense anyway, since all you know are relative values.

For a more advanced technical approach, using a calibrated microphone, you could reference everything using dB (SPL), as a reasonable standard, but this is a hassle, and not meaningful in your use case anyway.

Rationale:
The main reason that shifting by an arbitrary amount is that the log doesn't report the units of measurement. For example, even if you know the input amplitude is 0.1 Pascal, it's completely valid to say this is 100 milliPascal, where you'd be taking the log of 100 rather than 0.1 (so the log values are either 2 or -1). Both are completely valid and the choice is entirely arbitrary. When comparing to a standard reference, as in dB SPL, note that it's done as a ratio, log(P/Pref), removing the impact of changing the units.

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Thanks for the answer, I guess that makes sense. For others reading this, this idea confused me initially. However, adding/subtracting values from logs is obviously the same as scaling by a multiple before taking logs (i.e. (log(a/b) = log(a) - log(b)), and so essentially you are just scaling your inputs (e.g. divide everything by the value in the smallest bin, so your minimum value is 1. You'll need to add a small value to all bins so they are all non-zero. –  Mark Feb 15 at 9:39
@Mark: see my edit above for more on the rationale for shifting. (I added this in long after the answer, but it's been nagging at me that I needed to clarify this for subsequent readers.) –  tom10 Feb 27 at 16:54