I'm trying to determine how many steps it takes for the Runge-Kutta Method ("RK4") to be within 0.01% of the exact solution of an ordinary differential equation. I'm comparing this to the Euler method. Both should result in a straight line on a loglog plot. My Euler solution seems to be correct but I am getting a curved solution for RK. They are based on the same code so I am completely confused about the problem.
EDIT: Sorry for removing the wikipedia links. It wouldn't let me keep more than one link since I'm a new user. However, both methods are detailed on Wikipedia similarly to my implementation.
Should someone wish to tackle my problem, the code is below and graphs are in this Word file on dropbox.com. Yes this is a homework problem; I'm posting this because I'd like to understand what is wrong in my thought process.
f = @(x,y) x+y; %this is the eqn (the part after the @(t,y)
This is my RK4 code:
k1=@(x,y) h*f(x,y);
k2=@(x,y) h*f(x+1/2*h,y+1/2*k1(x,y));
k3=@(x,y) h*f(x+1/2*h,y+1/2*k2(x,y));
k4=@(x,y) h*f(x+h,y+k3(x,y));
clear y x exact i
x(1)=0;
y(1)=2;
xn=1;
x0=0;
exact=3*exp(xn)-xn-1; %exact solution at x=1
%# Evaluate RK4 with 1 step for x=0...1
N=1; %# number of steps
h=(xn-x0)/N; %# step size
i=1;
y(i+1)=y(i)+1/6*k1(x(i),y(i))+1/3*k2(x(i),y(i))+1/3*k3(x(i),y(i))+1/6*k4(x(i),y(i));
RK4(N)=y(i+1); %# store result of RK4 in vector RK4(# of steps)
E_RK4(N)=-(RK4(N)-exact)/exact*100;%keep track of %error for each N
Nsteps_RK4(N)=N;
%# repeat for increasing N until error is less than 0.01%
while -(RK4(N)-exact)/exact > 0.0001
i=1;
N=N+1;
h=(xn-x0)/N;
for i=1:N
y(i+1)=y(i)+1/6*k1(x(i),y(i))+1/3*k2(x(i),y(i))+1/3*k3(x(i),y(i))+1/6*k4(x(i),y(i));
x(i+1)=x(i)+h;
end
RK4(N)=y(i+1);
Nsteps_RK4(N)=N;
E_RK4(N)=-(RK4(N)-exact)/exact*100; %# keep track of %error for each N
end
Nsteps_RK4(end);
This is my Euler code:
%# Evaluate Euler with 1 step for x=0...1
clear y x i
x(1)=0;
y(1)=2;
N=1; %# number of steps
h=(xn-x0)/N; %# step size
i=1;
y(i+1)= y(i)+h*f(x(i),y(i));
Euler(N)=y(i+1); %# store result of Euler in vector Euler(# of steps)
E_Euler(N)=-(Euler(N)-exact)/exact*100;%# keep track of %error for each N
Nsteps_Euler(N)=N;
%# repeat for increasing N until error is less than 0.01%
while -(Euler(N)-exact)/exact > 0.0001
i=1;
N=N+1;
h=(xn-x0)/N;
for i=1:N
y(i+1)= y(i)+h*f(x(i),y(i));
x(i+1)=x(i)+h;
end
Euler(N)=y(i+1);
Nsteps_Euler(N)=N;
E_Euler(N)=-(Euler(N)-exact)/exact*100; %# keep track of %error for each N
end
fdefined? – stardt Oct 9 '11 at 22:34fyou are supposed to use. Also, can you make sure the Wikipedia article links I added correctly reflect the version of RK4 you are using? – Jonas Heidelberg Oct 9 '11 at 22:44his used in the anonymous functions before it is defined. You should useabs()in thewhileconditions because I don't see how you can guarantee that the estimate will always be less than the exact solution. You access the wrong element of theyvector after computing the values in theforloop. The line afterendshould beRK4(N) = y(N+1). The same mistakes are in the euler code. – stardt Oct 9 '11 at 22:50hin thewhileloop does not affect thehused in the k1...k4 functions. Consider:>> h = 1; >> g = @(x) x+h; >> g(0) ans = 1 >> h = 2; >> g(0) ans = 1– stardt Oct 9 '11 at 22:58h. The code as it is posted here will not run becausehis undefined. To see this, useclear allinstead of clearing only specific variables. Thehin yourkfunctions is whatever valuehhad when you defined those functions. I suggest using N=N*2 for the explicit Euler code to get the results much faster. – stardt Oct 10 '11 at 1:04