This is the problem I have to solve:

Write a program to evaluate and plot the Lagrange interpolant Iu(x) of u(x) = 1/(1+x^2) for x between -5 and 5. Do this for 5,7,9,11,13,15 point interpolants (5,7,9 etc. data points between, and including, -5 and 5). Your results should show both the function and the interpolant.

This is the code I have come up with so far:

int_pts = [5,7,9,11,13,15]; %various values for no. of point interpolants
n = length(int_pts);

u = @(x) 1./(1+x.^2); %the function we are interested in

numer = 1; 
denom = 1; %set initial values of numerator and denominator 

for k = 1 : n

    L = zeros( 1,int_pts(k) ); %create an array to store Lagrange polynomials 

    x = [-5 : 10/(int_pts(k)-1) : 5]; %create a list of x values

    udata = u(x); %create a list of corresponding values of u(x)

    for i = 1 : int_pts(k)

        if (i ~= k)

            denom = x(k) - x(i);

            syms z;
            numer = symfun( z - x(i) , z);        



        numer = numer * numer;
        denom = denom * denom;

        L(i) = numer / denom;



I think I'm on the right track, but I'm really starting to become stuck with how to extract the data and plot everything nicely. I've searched everywhere but most code seems to only want to output the value of the Lagrange polynomial for certain numbers i.e. P(2)=...


For the most part, what you have developed has lead you on the right path to solving your problem.

Some of the small issues you are running into are:

1) You are missing a for loop.

In lagrange interpolation you should have a summation of n terms, where n is the number of data points you have. And the terms are comprised of a product times the y component of the data point, i.e., yj*∏{(x - xi)/(xj - xi)}, where if i=j the term is skipped (this is done to make sure the denominator never is zero)

2) Your inner for loop and if statement don't play well together.

As soon as your script reaches the end of the if statement the for loop is broken and it continues to the next k value.

This should be replaced with a else followed by a continue.

3) When you generate your numer and denom variables you are unintentionally just squaring the new value and storing it to the variable.

You have numer = numer * numer this should be numer = numer * numer_temp

Here is a quick pseudo-code of the solution:

for n equals 'number of data points'

    Generate the n data points, P(x,y)

    for i equals 1 to n

        for j equals 1 to n

            if i is not equal to j
                Calculate Product of Numerators <- Function of x
                Calculate Product of Denominators
                Continue to next iteration of loop


        Calculate Lagrange Polynomial < Function of x

    Plot Lagrange
    Plot Original Function


And from this you can update your code to properly determine the Lagrange Polynomial.

u = @(x) 1./(1+x.^2); % The function we are interested in
number_of_data_Points = [5,7,9,11,13,15];

syms x; % Initializes x to be symbolic

for n = number_of_data_Points

    xn = linspace(-5,5,n);      % Creates x values
    yn = u(xn);                 % Creates y values

    L=0; % Re/Initializes Langrange Polynomial
    for j = 1:n
        numer = 1; % Re/Initializes Numerator
        denom = 1; % Re/Initializes Denominator
        for i = 1:n
            if j~=i
                denom_temp = xn(j) - xn(i);

                numer_temp = x - xn(i);    

                numer =  numer * numer_temp;
                denom = denom * denom_temp;
        L = L + yn(j) * numer / denom;
    L = matlabFunction(L);

I will leave changing the code, to output the results you require, to you.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.