76

I'm trying to draw a smooth curve in R. I have the following simple toy data:

> x
 [1]  1  2  3  4  5  6  7  8  9 10
> y
 [1]  2  4  6  8  7 12 14 16 18 20

Now when I plot it with a standard command it looks bumpy and edgy, of course:

> plot(x,y, type='l', lwd=2, col='red')

How can I make the curve smooth so that the 3 edges are rounded using estimated values? I know there are many methods to fit a smooth curve but I'm not sure which one would be most appropriate for this type of curve and how you would write it in R.

  • 1
    It entirely depends on what your data is and why you're smoothing it! Are the data counts? Densities? Measurements? What sort of measurement error might there be? What story are you trying to tell your readers with your graph? All of these issues affect whether and how you should smooth your data. – Harlan Aug 13 '10 at 20:28
  • These are measured data. At x values 1, 2, 3, ..., 10 some system made 2, 4, 6, ..., 20 errors. These coordinates should probably not be changed by the fitting algorithm. But I want to simulate the errors (y) at the missing x values, for example in the data, f(4)=8 and f(5)=7, so presumably f(4.5) is something between 7 and 8, using some polynomial or other smoothing. – Frank Aug 13 '10 at 20:35
  • 2
    In that case, with a single data point for each value of x, I wouldn't smooth at all. I'd just have big dots for my measured data points, with thin lines connecting them. Anything else suggests to the viewer that you know more about your data than you do. – Harlan Aug 13 '10 at 20:52
  • You may be right for this example. It's good to know how to do it though, and I might want to use it on some other data later, e.g. it makes sense if you have thousands of very spiky data points that kind of go up and down, but there is a general trend, for example going upward like here: plot(seq(1,100)+runif(100, 0,10), type='l'). – Frank Aug 13 '10 at 21:07
  • Here is a good way, stats.stackexchange.com/a/278666/134555 – Belter May 10 '17 at 10:48
93

I like loess() a lot for smoothing:

x <- 1:10
y <- c(2,4,6,8,7,12,14,16,18,20)
lo <- loess(y~x)
plot(x,y)
lines(predict(lo), col='red', lwd=2)

Venables and Ripley's MASS book has an entire section on smoothing that also covers splines and polynomials -- but loess() is just about everybody's favourite.

  • How do you apply it to this data? I'm not sure how because it expects a formula. Thanks! – Frank Aug 13 '10 at 20:30
  • 6
    As I showed you in the example when if x and y are visible variables. If they are columns of a data.frame named foo, the you add a data=foo option to the loess(y ~ x. data=foo) call -- just like in almost all other modeling functions in R. – Dirk Eddelbuettel Aug 13 '10 at 20:35
  • 4
    i also like supsmu() as an out-of-the-box smoother – apeescape Aug 13 '10 at 21:19
  • 4
    how would that work if x is a date parameter? If I try it with a data table that maps a date to a number (using lo <- loess(count~day, data=logins_per_day) ) I get this: Error: NA/NaN/Inf in foreign function call (arg 2) In addition: Warning message: NAs introduced by coercion – Wichert Akkerman Oct 24 '11 at 19:05
  • 1
    @Wichert Akkerman It seems that date format is hated by most R functions. I typically do something like new$date = as.numeric(new$date, as.Date("2015-01-01"), units="days") (as described on stat.ethz.ch/pipermail/r-help/2008-May/162719.html) – Mateusz Konieczny Mar 13 '16 at 13:25
57

Maybe smooth.spline is an option, You can set a smoothing parameter (typically between 0 and 1) here

smoothingSpline = smooth.spline(x, y, spar=0.35)
plot(x,y)
lines(smoothingSpline)

you can also use predict on smooth.spline objects. The function comes with base R, see ?smooth.spline for details.

26

In order to get it REALLY smoooth...

x <- 1:10
y <- c(2,4,6,8,7,8,14,16,18,20)
lo <- loess(y~x)
plot(x,y)
xl <- seq(min(x),max(x), (max(x) - min(x))/1000)
lines(xl, predict(lo,xl), col='red', lwd=2)

This style interpolates lots of extra points and gets you a curve that is very smooth. It also appears to be the the approach that ggplot takes. If the standard level of smoothness is fine you can just use.

scatter.smooth(x, y)
  • Great answer. Especially good for a high number of points – Federico Giorgi Jun 26 '18 at 23:38
24

the qplot() function in the ggplot2 package is very simple to use and provides an elegant solution that includes confidence bands. For instance,

qplot(x,y, geom='smooth', span =0.5)

produces enter image description here

  • Not to dodge the question, but I find the reporting of R^2 (or pseudo R^2) values for a smoothed fit to be dubious. A smoother will necessarily fit closer to the data as the bandwidth decreases. – Underminer Oct 14 '16 at 18:01
  • This may help: stackoverflow.com/questions/7549694/… – Underminer Oct 14 '16 at 18:08
  • Hmm, I could not finally run your code in R 3.3.1. I installed ggplot2 successfully bu cannot run qplot because it cannot find the function in Debian 8.5. – Léo Léopold Hertz 준영 Oct 14 '16 at 18:52
12

LOESS is a very good approach, as Dirk said.

Another option is using Bezier splines, which may in some cases work better than LOESS if you don't have many data points.

Here you'll find an example: http://rosettacode.org/wiki/Cubic_bezier_curves#R

# x, y: the x and y coordinates of the hull points
# n: the number of points in the curve.
bezierCurve <- function(x, y, n=10)
    {
    outx <- NULL
    outy <- NULL

    i <- 1
    for (t in seq(0, 1, length.out=n))
        {
        b <- bez(x, y, t)
        outx[i] <- b$x
        outy[i] <- b$y

        i <- i+1
        }

    return (list(x=outx, y=outy))
    }

bez <- function(x, y, t)
    {
    outx <- 0
    outy <- 0
    n <- length(x)-1
    for (i in 0:n)
        {
        outx <- outx + choose(n, i)*((1-t)^(n-i))*t^i*x[i+1]
        outy <- outy + choose(n, i)*((1-t)^(n-i))*t^i*y[i+1]
        }

    return (list(x=outx, y=outy))
    }

# Example usage
x <- c(4,6,4,5,6,7)
y <- 1:6
plot(x, y, "o", pch=20)
points(bezierCurve(x,y,20), type="l", col="red")
9

The other answers are all good approaches. However, there are a few other options in R that haven't been mentioned, including lowess and approx, which may give better fits or faster performance.

The advantages are more easily demonstrated with an alternate dataset:

sigmoid <- function(x)
{
  y<-1/(1+exp(-.15*(x-100)))
  return(y)
}

dat<-data.frame(x=rnorm(5000)*30+100)
dat$y<-as.numeric(as.logical(round(sigmoid(dat$x)+rnorm(5000)*.3,0)))

Here is the data overlaid with the sigmoid curve that generated it:

Data

This sort of data is common when looking at a binary behavior among a population. For example, this might be a plot of whether or not a customer purchased something (a binary 1/0 on the y-axis) versus the amount of time they spent on the site (x-axis).

A large number of points are used to better demonstrate the performance differences of these functions.

Smooth, spline, and smooth.spline all produce gibberish on a dataset like this with any set of parameters I have tried, perhaps due to their tendency to map to every point, which does not work for noisy data.

The loess, lowess, and approx functions all produce usable results, although just barely for approx. This is the code for each using lightly optimized parameters:

loessFit <- loess(y~x, dat, span = 0.6)
loessFit <- data.frame(x=loessFit$x,y=loessFit$fitted)
loessFit <- loessFit[order(loessFit$x),]

approxFit <- approx(dat,n = 15)

lowessFit <-data.frame(lowess(dat,f = .6,iter=1))

And the results:

plot(dat,col='gray')
curve(sigmoid,0,200,add=TRUE,col='blue',)
lines(lowessFit,col='red')
lines(loessFit,col='green')
lines(approxFit,col='purple')
legend(150,.6,
       legend=c("Sigmoid","Loess","Lowess",'Approx'),
       lty=c(1,1),
       lwd=c(2.5,2.5),col=c("blue","green","red","purple"))

Fits

As you can see, lowess produces a near perfect fit to the original generating curve. Loess is close, but experiences a strange deviation at both tails.

Although your dataset will be very different, I have found that other datasets perform similarly, with both loess and lowess capable of producing good results. The differences become more significant when you look at benchmarks:

> microbenchmark::microbenchmark(loess(y~x, dat, span = 0.6),approx(dat,n = 20),lowess(dat,f = .6,iter=1),times=20)
Unit: milliseconds
                           expr        min         lq       mean     median        uq        max neval cld
  loess(y ~ x, dat, span = 0.6) 153.034810 154.450750 156.794257 156.004357 159.23183 163.117746    20   c
            approx(dat, n = 20)   1.297685   1.346773   1.689133   1.441823   1.86018   4.281735    20 a  
 lowess(dat, f = 0.6, iter = 1)   9.637583  10.085613  11.270911  11.350722  12.33046  12.495343    20  b 

Loess is extremely slow, taking 100x as long as approx. Lowess produces better results than approx, while still running fairly quickly (15x faster than loess).

Loess also becomes increasingly bogged down as the number of points increases, becoming unusable around 50,000.

EDIT: Additional research shows that loess gives better fits for certain datasets. If you are dealing with a small dataset or performance is not a consideration, try both functions and compare the results.

3

In ggplot2 you can do smooths in a number of ways, for example:

library(ggplot2)
ggplot(mtcars, aes(wt, mpg)) + geom_point() +
  geom_smooth(method = "gam", formula = y ~ poly(x, 2)) 
ggplot(mtcars, aes(wt, mpg)) + geom_point() +
  geom_smooth(method = "loess", span = 0.3, se = FALSE) 

enter image description here enter image description here

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