Solving FitzHugh-Nagumo equations using ODE45

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Kate Heinzman
Kate Heinzman el 22 de Feb. de 2020
Comentada: darova el 22 de Feb. de 2020
Write a program to solve the FitzHugh-Nagumo equations for a single cell (i.e., without spatial coupling).
du/dt = c1u ( u a)(1 u) c2uv +stim
dv/ dt = b (u v)
where
a=0.13
b=0.013
c1=0.26
c2=0.1
stim is a stimulus current that can be applied for a short time at the beginning of the simulation.
u represents membrane potential and ranges from 0 (rest) to 1 (excited). v is a recovery variable in the same range. t is time in milliseconds.
How do you use MATLAB's ode45() function to integrate the system of differential equations? Input to the program should be the duration of the simulation; initial values for u, v, and t; the strength of the stimulus, and the time for which it is applied (typically a few ms). It;s output should include vectors for t, u and v.
  2 comentarios
darova
darova el 22 de Feb. de 2020
Once you mentioned ode45. Did you read help?
Kate Heinzman
Kate Heinzman el 22 de Feb. de 2020
Yes but I'm still confused as to how to write the overall function with the specified input and output arguments stated above.

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darova
darova el 22 de Feb. de 2020
Here is my achievement. I don't get about stim. Can you explain more?
% du/dt = c1u ( u − a)(1 − u) − c2uv +stim
% dv/ dt = b (u − v)
a = 0.13;
b = 0.013;
c1 = 0.26;
c2 = 0.1;
% let y(1) = u; y(2) = v
F = @(t,y) [c1*y(1)*(y(1)-a)*(1-y(1)-c2*y(1)*y(2)+stim)
b*(y(1)-y(2))];
tspan = [0 2]; % time
y0 = [1 2]; % u0 = 1; v0 = 2;
[t,y] = ode45(F,tspan,y0);
plot(t,y)
legend('u(t)','v(t)')
  4 comentarios
Kate Heinzman
Kate Heinzman el 22 de Feb. de 2020
I understand what you're saying but since stim is an input argument in the first function in my code it gives me an error when I try to use it in my second function. How do I pass stim from the first function to the second function?
darova
darova el 22 de Feb. de 2020
Just add it to input arguments?
function dUdt = fhn(t,U,stim)
Then call function
[t,U] = ode45(@(t,U)fhn(t,U,stim),[t0 tf],[u0; v0]);

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