Octave (electronics)

A frequency ratio expressed in octaves is the base-2 logarithm (binary logarithm) of the ratio:

: $\backslash text\{number\; of\; octaves\}\; =\; \backslash log\_2\backslash left(\backslash frac\{f\_2\}\{f\_1\}\backslash right)$

An amplifier or filter may be stated to have a frequency response of ±6 dB per octave over a particular frequency range, which signifies that the power gain changes by ±6 decibels (a factor of 4 in power), when the frequency changes by a factor of 2. This slope, or more precisely 10 log₁₀(4) ≈ 6 decibels per octave, corresponds to an amplitude gain proportional to frequency, which is equivalent to ±20 dB per decade (factor of 10 amplitude gain change for a factor of 10 frequency change). This would be a first-order filter.

The distance between the frequencies 20 Hz and 40 Hz is 1 octave. An amplitude of 52 dB at 4 kHz decreases as frequency increases at −2 dB/oct. What is the amplitude at 13 kHz?

: $\backslash text\{number\; of\; octaves\}\; =\; \backslash log\_2\backslash left(\backslash frac\{13\}\{4\}\backslash right)\; =\; 1.7$

: $\backslash text\{Mag\}\_\{13\backslash text\{\; kHz\}\}\; =\; 52\backslash text\{\; dB\}\; +\; (1.7\backslash text\{\; oct\}\; \backslash times\; -2\backslash text\{\; dB/oct\})\; =\; 48.6\backslash text\{\; dB\}.\backslash ,$

• Octave
• Octave band
• One-third octave

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Category:Acoustics

Category:Audio electronics