I am a beginner in R and I have tried to find information about the following without finding anything.

The green graph in the picture is composed by the red and yellow graphs. But let's say that I only have the data points of something like the green graph. How do I extract the low/high frequencies (i.e. approximately the red/yellow graphs) using a low pass/high pass filter?

Update: The graph was generated with

```
number_of_cycles = 2
max_y = 40
x = 1:500
a = number_of_cycles * 2*pi/length(x)
y = max_y * sin(x*a)
noise1 = max_y * 1/10 * sin(x*a*10)
plot(x, y, type="l", col="red", ylim=range(-1.5*max_y,1.5*max_y,5))
points(x, y + noise1, col="green", pch=20)
points(x, noise1, col="yellow", pch=20)
```

Update 2: Using the Butterworth filter in the `signal`

package suggested I get the following:

```
library(signal)
bf <- butter(2, 1/50, type="low")
b <- filter(bf, y+noise1)
points(x, b, col="black", pch=20)
bf <- butter(2, 1/25, type="high")
b <- filter(bf, y+noise1)
points(x, b, col="black", pch=20)
```

The calculations was a bit work, signal.pdf gave next to no hints about what values `W`

should have, but the original octave documentation at least mentioned radians which got me going. The values in my original graph was not chosen with any specific frequency in mind, so I ended up with the following not so simple frequencies: `f_low = 1/500 * 2 = 1/250`

, `f_high = 1/500 * 2*10 = 1/25`

and the sampling frequency `f_s = 500/500 = 1`

. Then I chose a f_c somewhere inbetween the low and high frequencies for the low/high pass filters (1/100 and 1/50 respectively).

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