# How to extract a specific frequency range from a .wav file?

I'm really new on sound processing, so maybe my question will be trivial. What I want to do is to extract a specific frequency range (let's say 150-400 Hz) from a wav file, using R. In other words, I want to create another wave file (wave2) that contains only the frequency component that I specify (150 to 400 Hz, or what else).

I read something on the net, and I discovered out that this can be done with a FFT analysis, and here's come the problems.

Suppose I've this code:

``````library(sound)
s1 <- Sine(440, 1)
s2 <- Sine(880, 1)
s3 <- s1 + s2

s3.s <- as.vector(s3\$sound)
# s3.s is now a vector, with length 44100;
# bitrate is 44100 (by default)
# so total time of s3 is 1sec.

# now I calculate frequencies
N <- length(s3.s)   # 44100
k <- c(0:(N-1))
Fs <- 44100         # sampling rate
T <- N / Fs
freq <- k / T
x <- fft(s3.s) / N

plot(freq[1:22050], x[1:22050], type="l") # we need just the first half of FFT computation
``````

The plot we obtain is:

Well, there are two peaks. If we want to know to what frequency they correspond, just find:

``````order(Mod(x)[1:22050], decreasing=T)[1:10]
[1] 441 881 882 880 883 442 440 879 884 878
``````

First two values are really near to the frequency I've used to create my sound:

``````        real     computed
Freq1: 440   |  441
Freq2: 880   |  881
``````

So, now comes the problem: how to proceed, if I want to delete from my sound the frequencies in the range, say, `(1, 500)` ? And how to select (and save) only the range `(1, 500)` ? What I attend, is that my new sound (with deleted frequencies) will be something near to simple `Sine(freq=880, duration=1)` (I know, it cannot be exactly like so!). Is that possible?

I'm pretty sure that `fft(DATA, inverse = TRUE)` is what I need. But I'm not sure, and however I don't know how to proceed.

-

``````order(Mod(x)[1:22050], decreasing=T)[1:10]
[1] 441 881 882 880 883 442 440 879 884 878
``````

Simply collect all values above 500:

``````junk <- order(Mod(x)[1:22050], decreasing=T)[1:10]
(junk1 <- junk[junk > 500])
[1] 881 882 880 883 879 884 878
``````

To generate the new signal simply repeat what you did to build the original signal:

``````junk2 <- Sine(0, 1)
for (i in 1:length(junk1)) {
junk2 <- junk2 + Sine(junk1[i], 1)
}
junk2.s <- as.vector(junk2\$sound)
``````

To keep the values below 500:

``````(junk3 <- junk[junk <= 500])
[1] 441 442 440
``````
-
Ops, it was too easy to be real XD Thanks for the answer! Just a quick question, that will probably be my next official question here: the resulting sound is terrible, not exactly what I was looking for. Do you know a way to improve the fft analysis? Is there a better approach to extract frequencies? –  Tommaso Sep 21 '11 at 19:20
@Tommaso; I think the "bad" sound is due to the multiple frequencies. From your program, try the following: `play(s1)` `play(s2)` and `play(s3)`. It is the mix of frequencies that causes the "bad" sound. Instead of extracting a range of frequencies, maybe you could pick the middle/median frequency in a range. –  bill_080 Sep 21 '11 at 19:50
@Tommaso; Oops, ran out of time.... Choosing a median frequency can be done by `(junk1 <- median(junk[junk > 500]))`. –  bill_080 Sep 21 '11 at 19:57
@Tommaso; After futzing around with `play()`, I noticed some screwy results. To make a long story short, try `play(s3)` and `play(s3/2)`. `s3` is made up of two frequencies. If you build up Z frequencies, divide by Z to play it. –  bill_080 Sep 21 '11 at 20:11
I came to your same conclusion. The problem is to scale the output in the range `(-1, 1)`. This can be done with the `normalize` function of the library `sound`. I tried to rebuild the original sound, after the fft analysis. Plotting `plot(normalize(s3[1:600]))`, and `plot(normalize(junk4[1:600]+junk2[1:600]))` (junk2 contains frequencies > 500, and junk4 frequencies < 500), will show you a pretty good result (although I have to find a better approximation). Thanks for your help bell! –  Tommaso Sep 21 '11 at 20:34