# cubic spline interpolation in R [closed]

I am trying an implementation of a cubic spline in R. I have already used the spline, smooth.spline and smooth.Pspline functions that are available in the R libraries but I am not that happy with the results so I want to convince myself about the consistency of the results by a "homemade" spline function. I have already computed the coefficients for the 3rd degree polynomials, but I am not sure how to plot the results..they seem random points. You can find the source code below. Any help would be appreciated.

``````x = c(35,36,39,42,45,48)
y = c(2.87671519825595, 4.04868309245341,   3.95202175000174,
3.87683188946186, 4.07739945984612,   2.16064840967985)

n = length(x)

#determine width of intervals
h=0
for (i in 1:(n-1)){
h[i] = (x[i+1] - x[i])
}

A = 0
B = 0
C = 0
D = 0
#determine the matrix influence coefficients for the natural spline
for (i in 2:(n-1)){
j = i-1
D[j] = 2*(h[i-1] + h[i])
A[j] = h[i]
B[j] = h[i-1]

}

#determine the constant matrix C
for (i in 2:(n-1)){
j = i-1
C[j] = 6*((y[i+1] - y[i]) / h[i] - (y[i] - y[i-1]) / h[i-1])
}

#maximum TDMA length
ntdma = n - 2

#tridiagonal matrix algorithm

#upper triangularization
R = 0
for (i in 2:ntdma){
R = B[i]/D[i-1]
D[i] = D[i] - R * A[i-1]
C[i] = C[i] - R * C[i-1]
}

#set the last C
C[ntdma] = C[ntdma] / D[ntdma]

#back substitute
for (i in (ntdma-1):1){
C[i] = (C[i] - A[i] * C[i+1]) / D[i]
}

#end of tdma

#switch from C to S
S = 0
for (i in 2:(n-1)){
j = i - 1
S[i] = C[j]
}
#end conditions
S[1] <- 0 -> S[n]

#Calculate cubic ai,bi,ci and di from S and h
for (i in 1:(n-1)){
A[i] = (S[i+ 1] - S[i]) / (6 * h[i])
B[i] = S[i] / 2
C[i] = (y[i+1] - y[i]) / h[i] - (2 * h[i] * S[i] + h[i] * S[i + 1]) / 6
D[i] = y[i]
}

#control points
xx = c(x[2],x[4])
yy = 0
#spline evaluation
for (j in 1:length(xx)){
for (i in 1:n){
if (xx[j]<=x[i]){
break
}
yy[i] = A[i]*(xx[j] - x[i])^3 + B[i]*(xx[j] - x[i])^2 + C[i]*(xx[j] - x[i]) + D[i]

}
points(x,yy ,col="blue")
}
``````

Thank you

-

## closed as too localized by Andrie, Joshua Ulrich, Ari B. Friedman, skolima, GravitonNov 24 '11 at 15:18

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Are you sure that this should be tagged R? This code doesn't make use of any of the R paradigms, e.g. vectorisation or applying functions. Rewrite this in R paradigm and I'll have a look. –  Andrie Nov 24 '11 at 11:23
OK, good luck then. –  Andrie Nov 24 '11 at 12:45
Cut n paste fail: Error in h[i] = (x[i + 1] - x[i]) : object 'h' not found. Also, yy is uninitialised. –  Spacedman Nov 24 '11 at 13:06
You don't have to make use of any higher level R functions to take advantage of vectorization. Your code looks very much like C, not R. I strongly suggest you take the time to learn how to 'think' in R, for which there are any number of excellent guides. P.S. When my results do not align with those of a published package, I generally first question my own results not the package's. To do otherwise is to have a G-d complex, which perhaps explains your choice of username. –  Ari B. Friedman Nov 24 '11 at 13:18
This is getting some down votes and some close requests. I think to keep it alive you need to do a spot of work on it. I'd suggest you point us to the source of the algorithm you are using, and also tell us how much of it you think is right so far - you say the results seem random points, but are the A's and B's and so on what you expect? –  Spacedman Nov 24 '11 at 14:04

Okay here goes...

Your 'control points' here are the points at which you are going to evaluate the cubic spline. So the number of points returned (yy) is the same length as xx. This made me spot something:

``````for (j in 1:length(xx)){
for (i in 1:n){
if (xx[j]<=x[i]){
break
}
yy[i] = A[i]*(xx[j] - x[i])^3 + B[i]*(xx[j] - x[i])^2 + C[i]*(xx[j] - x[i]) + D[i]

}
``````

This is only computing 'n' values of yy. Hullo, whats wrong here? It should be returning length(xx) values...

Then I think I spotted something else - your 'break' is going to drop out of the for loop. What you really want is to skip that i and go on to the next one until you hit the one relevant to your point:

``````#spline evaluation
for (j in 1:length(xx)){
for (i in 1:n){
if (xx[j]<=x[i]){
next
}
yy[j] = A[i]*(xx[j] - x[i])^3 + B[i]*(xx[j] - x[i])^2 + C[i]*(xx[j] - x[i]) + D[i]

}
}
``````

This is inefficient because you are computing some yy[j] and dumping them next time round the loop, but no matter, it gets the job done.

Wrap this into a function, so you can play with it easily. My function 'myspline' takes x and y for data to fit, and an xx vector for prediction locations. I can do:

``````> xx=seq(35,48,len=100)
> yy = myspline(x,y,xx)
> plot(xx,yy,type="l")
> points(x,y)
>
``````

And I get a nice curve going through the (x,y) points. Except for the first point which it seems to miss and heads off to zero, so I suspect there's still an off-by-one error somewhere. Oh well. 99% done.

Here's the code:

``````myspline <- function(x,y,xx){

n = length(x)

h=0;yy=0
#determine width of intervals
for (i in 1:(n-1)){
h[i] = (x[i+1] - x[i])
}

A = 0
B = 0
C = 0
D = 0
#determine the matrix influence coefficients for the natural spline
for (i in 2:(n-1)){
j = i-1
D[j] = 2*(h[i-1] + h[i])
A[j] = h[i]
B[j] = h[i-1]

}

#determine the constant matrix C
for (i in 2:(n-1)){
j = i-1
C[j] = 6*((y[i+1] - y[i]) / h[i] - (y[i] - y[i-1]) / h[i-1])
}

#maximum TDMA length
ntdma = n - 2

#tridiagonal matrix algorithm

#upper triangularization
R = 0
for (i in 2:ntdma){
R = B[i]/D[i-1]
D[i] = D[i] - R * A[i-1]
C[i] = C[i] - R * C[i-1]
}

#set the last C
C[ntdma] = C[ntdma] / D[ntdma]

#back substitute
for (i in (ntdma-1):1){
C[i] = (C[i] - A[i] * C[i+1]) / D[i]
}

#end of tdma

#switch from C to S
S = 0
for (i in 2:(n-1)){
j = i - 1
S[i] = C[j]
}
#end conditions
S[1] <- 0 -> S[n]

#Calculate cubic ai,bi,ci and di from S and h
for (i in 1:(n-1)){
A[i] = (S[i+ 1] - S[i]) / (6 * h[i])
B[i] = S[i] / 2
C[i] = (y[i+1] - y[i]) / h[i] - (2 * h[i] * S[i] + h[i] * S[i + 1]) / 6
D[i] = y[i]
}

#control points
#xx = seq(x[2],x[4],len=100)

#spline evaluation
for (j in 1:length(xx)){
for (i in 1:n){
if (xx[j]<=x[i]){
next
}
yy[j] = A[i]*(xx[j] - x[i])^3 + B[i]*(xx[j] - x[i])^2 + C[i]*(xx[j] - x[i]) + D[i]
}
}
return(yy)
}
``````
-
+1 For beatification-worthy effort. –  Ari B. Friedman Nov 24 '11 at 17:42
It's the only way I'll attain sainthood. Or 10k rep... –  Spacedman Nov 24 '11 at 19:07
@Spacedman Thank you. You are right, the spline is a bit shifted, but I will manage to correct it. ..probably a loop somewhere. And after I will get it into a more R specific "shape". Thank you once again for your help. Not like the others so called experts that are just good at flapping their fingers and criticize without helping any. Well I'm off... daddamn it's hard to walk straight with all this f**ed up blood of mine. Thank you man. See you later ;] –  Marius Nov 25 '11 at 9:02
hehe. there's a lot of things in there that can be optimised by doing vectors all in one go and not having loops, but some of your code wont admit to that because its a bit recursive - x[i+1] depending on x[i] and so on. If you want help on that process, create some simple, isolated, reproducible (cut n paste) examples as new questions and I'm sure the guys will have a go! –  Spacedman Nov 25 '11 at 10:24
well the optimization was not the point here. The thing is that I applied already 3 different smoothing techniques (2 built in and one implemented) on the data and I wanted to have a fourth one to see how much data I am losing if the data points are close enough or scattered. I still have to apply a smoothing parameter on the second derivative, but again it was just for comparison purposes. It is pretty much sensitive data that I deal with and I will also pass it through the Matlab smoothing functions. I am a noob in R as I just started using it 3 weeks ago, so..yeah.. optimization is far away –  Marius Nov 25 '11 at 10:37