I'm trying to write a cubic spline interpolation program. I have written the program but, the graph is not coming out correctly. The spline uses natural boundary conditions(second dervative at start/end node are 0). The code is in Matlab and is shown below,

clear all
%Function to Interpolate
k = 10;                    %Number of Support Nodes-1
xs(1) = -1;
for j = 1:k
    xs(j+1) = -1 +2*j/k;   %Support Nodes(Equidistant)
fs = 1./(25.*xs.^2+1);     %Support Ordinates
x = [-0.99:2/(2*k):0.99];  %Places to Evaluate Function
fx = 1./(25.*x.^2+1);      %Function Evaluated at x

%Cubic Spline Code(Coefficients to Calculate 2nd Derivatives)

f(1) = 2*(xs(3)-xs(1));
g(1) = xs(3)-xs(2);
r(1) = (6/(xs(3)-xs(2)))*(fs(3)-fs(2)) + (6/(xs(2)-xs(1)))*(fs(1)-fs(2));
e(1) = 0;

for i = 2:k-2
    e(i) = xs(i+1)-xs(i);
    f(i) = 2*(xs(i+2)-xs(i));
    g(i) = xs(i+2)-xs(i+1);
    r(i) = (6/(xs(i+2)-xs(i+1)))*(fs(i+2)-fs(i+1)) + ...
e(k-1) = xs(k)-xs(k-1);
f(k-1) = 2*(xs(k+1)-xs(k-1));
r(k-1) = (6/(xs(k+1)-xs(k)))*(fs(k+1)-fs(k)) + ...

%Tridiagonal System

i = 1;
A = zeros(k-1,k-1);
while i < size(A)+1;
    A(i,i) = f(i);
    if i < size(A);
        A(i,i+1) = g(i);
        A(i+1,i) = e(i);
    i = i+1;

for i = 2:k-1                             %Decomposition
    e(i) = e(i)/f(i-1);
    f(i) = f(i)-e(i)*g(i-1);

for i = 2:k-1                             %Forward Substitution 
    r(i) = r(i)-e(i)*r(i-1);

xn(k-1)= r(k-1)/f(k-1);
for i = k-2:-1:1                          %Back Substitution
    xn(i) = (r(i)-g(i)*xn(i+1))/f(i);


if (max(xs) <= max(x))
    error('Outside Range'); 

if (min(xs) >= min(x))
    error('Outside Range'); 

P = zeros(size(length(x),length(x)));
i = 1;
for Counter = 1:length(x)
    for j = 1:k-1
        a(j) = x(Counter)- xs(j);
    i = find(a == min(a(a>=0)));
    if i == 1
        c1 = 0;
        c2 = xn(1)/6/(xs(2)-xs(1));
        c3 = fs(1)/(xs(2)-xs(1));
        c4 = fs(2)/(xs(2)-xs(1))-xn(1)*(xs(2)-xs(1))/6;
        t1 = c1*(xs(2)-x(Counter))^3;
        t2 = c2*(x(Counter)-xs(1))^3;
        t3 = c3*(xs(2)-x(Counter));
        t4 = c4*(x(Counter)-xs(1));
        P(Counter) = t1 +t2 +t3 +t4;
        if i < k-1
        c1 = xn(i-1+1)/6/(xs(i+1)-xs(i-1+1));
        c2 = xn(i+1)/6/(xs(i+1)-xs(i-1+1));
        c3 = fs(i-1+1)/(xs(i+1)-xs(i-1+1))-xn(i-1+1)*(xs(i+1)-xs(i-1+1))/6;
        c4 = fs(i+1)/(xs(i+1)-xs(i-1+1))-xn(i+1)*(xs(i+1)-xs(i-1+1))/6;
        t1 = c1*(xs(i+1)-x(Counter))^3;
        t2 = c2*(x(Counter)-xs(i-1+1))^3;
        t3 = c3*(xs(i+1)-x(Counter));
        t4 = c4*(x(Counter)-xs(i-1+1));
        P(Counter) = t1 +t2 +t3 +t4;
        c1 = xn(i-1+1)/6/(xs(i+1)-xs(i-1+1));
        c2 = 0;
        c3 = fs(i-1+1)/(xs(i+1)-xs(i-1+1))-xn(i-1+1)*(xs(i+1)-xs(i-1+1))/6;
        c4 = fs(i+1)/(xs(i+1)-xs(i-1+1));
        t1 = c1*(xs(i+1)-x(Counter))^3;
        t2 = c2*(x(Counter)-xs(i-1+1))^3;
        t3 = c3*(xs(i+1)-x(Counter));
        t4 = c4*(x(Counter)-xs(i-1+1));
        P(Counter) = t1 +t2 +t3 +t4;

P = P';
P(length(x)) = NaN;


When I run the code, the interpolation function is not symmetric and, it doesn't converge correctly. Can anyone offer any suggestions about problems in my code? Thanks.


I wrote a cubic spline package in Mathematica a long time ago. Here is my translation of that package into Matlab. Note I haven't looked at cubic splines in about 7 years, so I'm basing this off my own documentation. You should check everything I say.

The basic problem is we are given n data points (x(1), y(1)) , ... , (x(n), y(n)) and we wish to calculate a piecewise cubic interpolant. The interpolant is defined as

   S(x) = {  Sk(x)   when x(k) <= x <= x(k+1)
          {  0       otherwise 

Here Sk(x) is a cubic polynomial of the form

  Sk(x) = sk0 + sk1*(x-x(k)) + sk2*(x-x(k))^2 + sk3*(x-x(k))^3

The properties of the spline are:

  1. The spline pass through the data point Sk(x(k)) = y(k)
  2. The spline is continuous at the end-points and thus continuous everywhere in the interpolation interval Sk(x(k+1)) = Sk+1(x(k+1))
  3. The spline has continuous first derivative Sk'(x(k+1)) = Sk+1'(x(k+1))
  4. The spline has continuous second derivative Sk''(x(k+1)) = Sk+1''(x(k+1))

To construct a cubic spline from a set of data point we need to solve for the coefficients sk0, sk1, sk2 and sk3 for each of the n-1 cubic polynomials. That is a total of 4*(n-1) = 4*n - 4 unknowns. Property 1 supplies n constraints, and properties 2,3,4 each supply an additional n-2 constraints. Thus we have n + 3*(n-2) = 4*n - 6 constraints and 4*n - 4 unknowns. This leaves two degrees of freedom. We fix these degrees of freedom by setting the second derivative equal to zero at the start and end nodes.

Let m(k) = Sk''(x(k)) , h(k) = x(k+1) - x(k) and d(k) = (y(k+1) - y(k))/h(k). The following three-term recurrence relation holds

  h(k-1)*m(k-1) + 2*(h(k-1) + h(k))*m(k) + h(k)*m(k+1) = 6*(d(k) - d(k-1))

The m(k) are unknowns we wish to solve for. The h(k) and d(k) are defined by the input data. This three-term recurrence relation defines a tridiagonal linear system. Once the m(k) are determined the coefficients for Sk are given by

   sk0 = y(k)
   sk1 = d(k) - h(k)*(2*m(k) + m(k-1))/6
   sk2 = m(k)/2
   sk3 = m(k+1) - m(k)/(6*h(k))

Okay that is all the math you need to know to completely define the algorithm to compute a cubic spline. Here it is in Matlab:

function [s0,s1,s2,s3]=cubic_spline(x,y)

if any(size(x) ~= size(y)) || size(x,2) ~= 1
   error('inputs x and y must be column vectors of equal length');

n = length(x)

h = x(2:n) - x(1:n-1);
d = (y(2:n) - y(1:n-1))./h;

lower = h(1:end-1);
main  = 2*(h(1:end-1) + h(2:end));
upper = h(2:end);

T = spdiags([lower main upper], [-1 0 1], n-2, n-2);
rhs = 6*(d(2:end)-d(1:end-1));

m = T\rhs;

% Use natural boundary conditions where second derivative
% is zero at the endpoints

m = [ 0; m; 0];

s0 = y;
s1 = d - h.*(2*m(1:end-1) + m(2:end))/6;
s2 = m/2;
s3 =(m(2:end)-m(1:end-1))./(6*h);

Here is some code to plot a cubic spline:

function plot_cubic_spline(x,s0,s1,s2,s3)

n = length(x);

inner_points = 20;

for i=1:n-1
   xx = linspace(x(i),x(i+1),inner_points);
   xi = repmat(x(i),1,inner_points);
   yy = s0(i) + s1(i)*(xx-xi) + ... 
     s2(i)*(xx-xi).^2 + s3(i)*(xx - xi).^3;

Here is a function that constructs a cubic spline and plots in on the famous Runge function:

function cubic_driver(num_points)

runge = @(x) 1./(1+ 25*x.^2);

x = linspace(-1,1,num_points);
y = runge(x);

[s0,s1,s2,s3] = cubic_spline(x',y');

plot_points = 1000;
xx = linspace(-1,1,plot_points);
yy = runge(xx);

hold on;

You can see it in action by running the following at the Matlab prompt

 >> cubic_driver(5)
 >> clf 
 >> cubic_driver(10)
 >> clf
 >> cubic_driver(20)

By the time you have twenty nodes your interpolant is visually indistinguishable from the Runge function.

Some comments on the Matlab code: I don't use any for or while loops. I am able to vectorize all operations. I quickly form the sparse tridiagonal matrix with spdiags. I solve it using the backslash operator. I counting on Tim Davis's UMFPACK to handle the decomposition and forward and backward solves.

Hope that helps. The code is available as a gist on github https://gist.github.com/1269709


There was a bug in spline function, generated (n-2) by (n-2) should be symmetric:

lower = h(2:end);
main  = 2*(h(1:end-1) + h(2:end));
upper = h(1:end-1);


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