In a previous post, we talked about that higher order interpolation is a bad idea.

In this post I am showing you a MATLAB program that will allow you to experiment by changing the number of data points you choose, that is, the value of n (see the input highlighted in red in the code – this is the only line you want to change) and see for yourself why high order interpolation is a bad idea. Just, cut and paste the code below (or download it from http://www.eng.usf.edu/~kaw/download/runge.m) in the MATLAB editor and run it.

### % Simulation : Higher Order Interpolation is a Bad Idea

% Language : Matlab r12

% Authors : Autar Kaw

% Last Revised : June 10 2008

% Abstract: In 1901, Carl Runge published his work on dangers of high order

% interpolation. He took a simple looking function f(x)=1/(1+25x^2) on

% the interval [-1,1]. He took points equidistantly spaced in [-1,1]

% and interpolated the points with polynomials. He found that as he

% took more points, the polynomials and the original curve differed

% even more considerably. Try n=5 and n=25

clc

clear all

clf

disp(‘In 1901, Carl Runge published his work on dangers of high order’)

disp(‘interpolation. He took a simple looking function f(x)=1/(1+25x^2) on’)

disp(‘the interval [-1,1]. He took points equidistantly spaced in [-1,1]’)

disp(‘and interpolated the points with a polynomial. He found that as he’)

disp(‘took more points, the polynomials and the original curve differed’)

disp(‘even more considerably. Try n=5 and n=15’)

%

% INPUT:

% Enter the following

% n= number of equidisant x points from -1 to +1

n=15;

% SOLUTION

disp(‘ ‘)

disp(‘SOLUTION’)

disp(‘Check out the plots to appreciate: High order interpolation is a bad idea’)

fprintf(‘\nNumber of data points used =%g’,n)

% h = equidisant spacing between points

h=2.0/(n-1);

syms xx

% generating n data points equally spaced along the x-axis

% First data point

x(1)=-1;

y(1)=subs(1/(1+25*xx^2),xx,-1);

% Other data points

for i=2:1:n

x(i)=x(i-1)+h;

y(i)=subs(1/(1+25*xx^2),xx,x(i));

end

% Generating the (n-1)th order polynomial from the n data points

p=polyfit(x,y,n-1);

% Generating the points on the polynomial for plotting

xpoly=-1:0.01:1;

ypoly=polyval(p,xpoly);

% Generating the points on the function itself for plotting

xfun=-1:0.01:1;

yfun=subs(1/(1+25*xx^2),xx,xfun);

% The classic plot

% Plotting the points

plot(x,y,’o’,’MarkerSize’,10)

hold on

% Plotting the polynomial curve

plot(xpoly,ypoly,’LineWidth’,3,’Color’,’Blue’)

hold on

% Plotting the origianl function

plot(xfun,yfun,’LineWidth’,3,’Color’,’Red’)

hold off

xlabel(‘x’)

ylabel(‘y’)

title(‘Runges Phenomena Revisited’)

legend(‘Data points’,’Polynomial Interpolant’,’Original Function’)

%***********************************************************************

disp(‘ ‘)

disp(‘ ‘)

disp(‘What you will find is that the polynomials diverge for’)

disp(‘0.726<|x|<1. If you started to choose same number of points ‘)

disp(‘but more of them close to -1 and +1, you would avoid such divergence. ‘)

disp(‘ ‘)

disp(‘However, there is no general rule to pick points for a general ‘)

disp(‘function so that this divergence is avoided; but some rules do exist for ‘)

disp(‘certian types of functions.’)

This post is brought to you by Holistic Numerical Methods: Numerical Methods for the STEM undergraduate at http://numericalmethods.eng.usf.edu

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