Representation of the amplitude on a logarithmic scale approximates the sensitivity of the human auditory system, and therefore gives you a better representation of what you hear, as compared to a non-logarithmic scale. Mathematically, all you have to do is:

```
Alog = 20*log10 (abs (A))
```

Where `A`

is the amplitude of the FFT data, and `Alog`

is the output. the factor of `20`

is just a convention and has no effect on the image, which you probably scale anyway to a color-scheme.

**EDIT**

Explanation regarding the `20`

factor: The dB (decibel) unit is a logarithmic unit measuring **ratios**: it represents a scale on which the distance between 100 and 10, is the same as between 1000 and 100 (since they have the same ratio: 1000/100 = 100/10). If you measure it in dB you get:

```
10*log10 (1000/100) = 10*log10 (100/10) = 10
```

The factor of `10`

is because `deci`

means `tenth`

, which means 1 Bel is 10 deciBels, (like 1 kilogram is 1000 grams)

Since the human auditory system is also (approximately) measuring ratios, it makes sense to measure sound level on a logarithmic scale, i.e measure the ratio of sound level to some reference value. Since the level of a sound is associated with the power (in Watts) of the sound wave, you actually measure the ratio of powers P/Pref. Also, the power is proportional to the amplitude squared, so all in all you get:

```
10*log10 (P/Pref) = 10*log10 (A^2 / Aref^2) = 20*log10 (A/Aref)
```

by the log rules. That's the origin of the `20`

factor - remember that in the computer the audio is represented by the instantaneous amplitude of the sound wave.