# How do I run a high pass or low pass filter on data points in R?

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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If you give us a reproducible example, eg the data / code you used for the graph, people will be able to help you more easily. It would help to show us what you tried until now. –  Joris Meys Aug 18 '11 at 10:33
To add : the signal package contains all kind of filters for this : cran.r-project.org/web/packages/signal/signal.pdf –  Joris Meys Aug 18 '11 at 10:35
this is in any case a far too broad programming question. You should at least specify which filter you want to use. There is a whole number of options which may or may not make sense on your real data. –  Joris Meys Aug 18 '11 at 17:31
@Joris Please make your comment about signals into an answer, and I'll accpet that. It was what I was looking for (though I find that I have to do a massive relearning of what I learned about filters years ago...). –  hlovdal Aug 19 '11 at 0:33
thx for the update. I added an answer. –  Joris Meys Aug 19 '11 at 8:26

Per request of OP:

The signal package contains all kinds of filters for signal processing. Most of it is comparable to / compatible with the signal processing functions in Matlab/Octave.

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I bumped into similar problem recently and did not find the answers here particularly helpful. Here is an alternative approach.

Let´s start by defining the example data from the question:

``````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)
y <- y + noise1

plot(x, y, type="l", ylim=range(-1.5*max_y,1.5*max_y,5), lwd = 5, col = "green")
``````

So the green line is the dataset we want to low-pass and high-pass filter.

Side note: The line in this case could be expressed as a function by using cubic spline (`spline(x,y, n = length(x))`), but with real world data this would rarely be the case, so let's assume that it is not possible to express the dataset as a function.

The easiest way to smooth such data I have came across is to use `loess` or `smooth.spline` with appropriate `span`/`spar`. According to statisticians loess/smooth.spline is probably not the right approach here, as it does not really present a defined model of the data in that sense. An alternative is to use Generalized Additive Models (`gam()` function from package mgcv). My argument for using loess or smoothed spline here is that it is easier and does not make a difference as we are interested in the visible resulting pattern. Real world datasets are more complicated than in this example and finding a defined function for filtering several similar datasets might be difficult. If the visible fit is good, why to make it more complicated with R2 and p values? To me the application is visual for which loess/smoothed splines are appropriate methods. Both of the methods assume polynomial relationships with the difference that loess is more flexible also using higher degree polynomials, while cubic spline is always cubic (x^2). Which one to use depends on trends in a dataset. That said, the next step is to apply a low-pass filter on the dataset by using `loess()` or `smooth.spline()`:

``````lowpass.spline <- smooth.spline(x,y, spar = 0.6) ## Control spar for amount of smoothing
lowpass.loess <- loess(y ~ x, data = data.frame(x = x, y = y), span = 0.3) ## control span to define the amount of smoothing

lines(predict(lowpass.spline, x), col = "red", lwd = 2)
lines(predict(lowpass.loess, x), col = "blue", lwd = 2)
``````

Red line is the smoothed spline filter and blue the loess filter. As you see results differ slightly. I guess one argument of using GAM would be to find the best fit, if the trends really were this clear and consistent among datasets, but for this application both of these fits are good enough for me.

After finding a fitting low-pass filter, the high-pass filtering is as simple as subtracting the low-pass filtered values from `y`:

``````highpass <- y - predict(lowpass.loess, x)
lines(x, highpass, lwd =  2)
``````

This answer comes late, but I hope it helps someone else struggling with similar problem.

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Thank you, excellent answer. I'll remember this for next time I'll run into this kind of problem. –  hlovdal Apr 8 '14 at 13:29

Use filtfilt function instead of filter (package signal) to get rid of signal shift.

``````library(signal)
bf <- butter(2, 1/50, type="low")
b1 <- filtfilt(bf, y+noise1)
points(x, b1, col="red", pch=20)
``````

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Check out this link where there's R code for filtering (medical signals). It's by Matt Shotwell and the site is full of interesting R/stats info with a medical bent:

biostattmat.com

The package fftfilt contains lots of filtering algorithms that should help too.

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there's a package for that. Copying a manual implementation of a very basic filter from which you don't know whether it would actually perform, is not a good idea. –  Joris Meys Aug 18 '11 at 10:38

there is a package on CRAN named `FastICA`, this computes the approximation of the independent source signals, however in order to compute both signals you need a matrix of at least 2xn mixed observations (for this example), this algorithm can't determine the two indpendent signals with just 1xn vector. See the example below. hope this can help you.

``````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)
######################################################
library(fastICA)
S <- cbind(y,noise1)#Assuming that "y" source1 and "noise1" is source2
A <- matrix(c(0.291, 0.6557, -0.5439, 0.5572), 2, 2) #This is a mixing matrix
X <- S %*% A

a <- fastICA(X, 2, alg.typ = "parallel", fun = "logcosh", alpha = 1,
method = "R", row.norm = FALSE, maxit = 200,
tol = 0.0001, verbose = TRUE)

par(mfcol = c(2, 3))
plot(S[,1 ], type = "l", main = "Original Signals",
xlab = "", ylab = "")
plot(S[,2 ], type = "l", xlab = "", ylab = "")
plot(X[,1 ], type = "l", main = "Mixed Signals",
xlab = "", ylab = "")
plot(X[,2 ], type = "l", xlab = "", ylab = "")
plot(a\$S[,1 ], type = "l", main = "ICA source estimates",
xlab = "", ylab = "")
plot(a\$S[, 2], type = "l", xlab = "", ylab = "")
``````
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I am not sure if any filter is the best way for You. More useful instrument for that aim is the fast Fourier transformation.

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