@Hrishikesh Das Did you found the problem and did you make it?
Forward Euler method for Higher order differential equation
55 vues (au cours des 30 derniers jours)
Afficher commentaires plus anciens
Helloo!
I am trying to solve a third order differential equation using forward euler method. The differential equation is : y''' = 2 y'' + 6y ; y(0) =1, y'(0) = 0, y''(0)=1, interval is [0, 5], step size= 0.001. here the derivative is with respect to time (t). I dont know how to proceed further and do the iteration. I tried to change the above differential equation into a first order differential equation but then I dont know how to proceed with the code.
y(1) = y ;
y(2) = y' = y(1)'
y(3) = y'' = y(2)'
y(3)' = 2 y(3) + 6 y(1)
Below is a code which I used to solve first order differential equation using euler method. Please help.
clear
close all
clc
%%
t0 = 0; %initial value
y0 = 1; %initial condition(given)
tEnd = 5; %end of time step
h = 0.001; %step size
N = (tEnd-t0)/h; %number of interval
T = t0:h:tEnd;
Y = zeros(1, N+1);
Y(1) = y0;
for i = 1:N
fi = %function
Y(i+ 1) = Y(i) + h * fi;
end
%%
%ploting===================================================================
plot(T,Y,'.','LineWidth',2);
title('Approximate solution Euler Explicit Method')
Réponse acceptée
James Tursa
le 28 Avr 2020
You need to think of Y as your three element column vector as you have defined. So at each step you are dealing with a column vector. E.g.,
Y = zeros(3, N+1); % <-- a series of 3-element column vectors
Y(:,1) = [1;0;1]; % <-- initial value is a 3-element column vector of [ y ; y' ; y'' ]
for i = 1:N
fi = %function, which needs to calculate a 3-element derivative column vector
Y(:,i+1) = Y(:,i) + h * fi; % <-- each step works with columns of Y
2 commentaires
James Tursa
le 28 Avr 2020
Modifié(e) : James Tursa
le 28 Avr 2020
Just take your definitions:
y(2) = y' = y(1)'
y(3) = y'' = y(2)'
y(3)' = 2 y(3) + 6 y(1)
and write a 3-element fi vector based on that. The outline is
fi = [ y(1)' ; y(2)' ; y(3)' ]; % <-- you fill this in based on the above three lines
Now you fill in the above three elements based on your definitions in terms of y(1), y(2), and y(3), and that becomes your code. E.g., that first spot for y(1)' using your definitions is simply y(2), so y(2) would be the first element of fi. But remember we are dealing with columns of Y in your actual code, so for you actual code y(2) at time point i is Y(2,i). So you would have
fi = [ Y(2,i) ; y(2)' ; y(3)' ]; % <-- you fill this in based on the above three lines
Do this for the other two elements.
Plus de réponses (1)
Ameer Hamza
le 28 Avr 2020
You can download the zip file given in this answer: https://www.mathworks.com/matlabcentral/answers/98293-is-there-a-fixed-step-ordinary-differential-equation-ode-solver-in-matlab-8-0-r2012b#answer_107643 and study the code of ode1.m. It is the implementation of the Euler method provided by Mathworks in very early releases of MATLAB. It is no longer included in MATLAB by default, but it is still useful to understand the implementation of the Euler method for higher-order ODEs.
4 commentaires
Ameer Hamza
le 28 Avr 2020
You can see James' answer. You can follow that hint to implement multiple ODEs using Euler.
Voir également
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!
Translated by 
Vous pouvez également sélectionner un site web dans la liste suivante :
Amériques
- América Latina (Español)
- Canada (English)
- United States (English)
Europe
- Belgium (English)
- Denmark (English)
- Deutschland (Deutsch)
- España (Español)
- Finland (English)
- France (Français)
- Ireland (English)
- Italia (Italiano)
- Luxembourg (English)
- Netherlands (English)
- Norway (English)
- Österreich (Deutsch)
- Portugal (English)
- Sweden (English)
- Switzerland
- United Kingdom (English)
Asie-Pacifique
- Australia (English)
- India (English)
- New Zealand (English)
- 中国
- 日本Japanese (日本語)
- 한국Korean (한국어)