forward, backward, central finite differences with step sizes.

66 views (last 30 days)
Steven Deng
Steven Deng on 20 Oct 2022
Commented: ahmed on 20 May 2023
I have to develop a code that can differentiate functions by using forward, backward, and central finite difference approaches, and I need to use varying step sizes to make the program run at higher accuracies. I also need to show an analytical solution showing the exact solution. So far I have this:
clc; clear; close all;
Fun = @(x) x.^2; %function
dFun = @(x) 2.*x; %derivative
x=linspace(-3,3,101); %from x = -3 to 3
F=Fun(x);
h=x(2)-x(1);
xCentral=x(2:end-1); %Central Difference Approach
dFCentral=(F(3:end)-F(1:end-2))/(2*h);
xForward=x(1:end-1); %Forward Difference Approach
dFForward=(F(2:end)-F(1:end-1))/h;
xBackward=x(2:end); %Backward Difference Approach
dFBackward=(F(2:end)-F(1:end-1))/h;
plot(x,dFun(x)); %Exact solution
hold on
plot(xCentral,dFCentral,'r')
plot(xForward,dFForward,'k');
plot(xBackward,dFBackward,'g');
legend('Analytic','Central','Forward','Backward') %Plot everything
However, I dont know how to implement a step size into the program, how would I do this?
  1 Comment
ahmed
ahmed on 20 May 2023
use matlab code to find the approximation of the solution sinh-1(x) by using backward

Sign in to comment.

Sign in to answer this question.

Answers (1)

Davide Masiello
Davide Masiello on 21 Oct 2022
Edited: Davide Masiello on 21 Oct 2022
Ran in:
I took the liberty to give you an example with a different function, because the one in your question has a constant slope and different step sizes produce the same result, hence it's difficult to visualize. Also, I did it only for the central difference case.
Fun = @(x) x.^3; % Function
dFun = @(x) 3*x.^2; % First order derivative
fplot(dFun,[-3,3],'.'),hold on % Plot of first order derivative
h = [1 0.5 0.1]; % Three different step sizes
for i = 1:3 % Loops over step sizes
x = -3:h(i):3; % Creates x array depending on step size
xd = x(2:end-1); % Removes boundaries (can't be approximated with central difference)
dFc = (Fun(x(3:end))-Fun(x(1:end-2)))/(2*h(i)); % Central difference scheme
plot(x(2:end-1),dFc) % Plot the result
end
legend('Analytic','h = 1','h = 0.5','h = 0.1','Location','best')

Categories

Find more on Descriptive Statistics and Visualization in Help Center and File Exchange

Tags

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!