Solving an ODE in matlab

6 visualizaciones (últimos 30 días)
Kebels3
Kebels3 el 11 de Mzo. de 2020
Comentada: Bjorn Gustavsson el 11 de Mzo. de 2020
Can you guys help me?
?̈(?) = -(0.1/50) ?̇(?)-2?(?)
How to numerically integrate to find a solution for ??
Speed of the mass in time-step ? + Δ? is:
?̇(? + Δ?) ≈ ?̇(?) + ?̈(?) Δ?
and the position in time-step ? + Δ? is:
?(? + Δ?) ≈ ?(?) + ?̇(?) Δ?
I want to put the previous two equations in a loop and loop from ? = 0 s to ? = 10 s(step Δ? = 0.001 s). And then plot those two graphs into in graph.
Assuming the mass is let go from initial displacement ?(0) = 0.5 m.
But I can’t get it to work in matlab.

Iniciar sesión para responder a esta pregunta.

Respuesta aceptada

Ameer Hamza
Ameer Hamza el 11 de Mzo. de 2020
Editada: Ameer Hamza el 11 de Mzo. de 2020
You can use ode45 to solve such ODEs. See this example: https://www.mathworks.com/help/matlab/ref/ode45.html#bu3uj8b to see how your differential equation is converted into two first order ODEs.
fun = @(t, x) [x(2); -0.1/50*x(2) - 2*x(1)];
time = 0:0.001:10;
initial_condition = [0.5 0];
[t, y] = ode45(fun, time, initial_condition);
plot(t,y)
legend({'position', 'velocity'});
  5 comentarios
Mostrar 3 comentarios más antiguos
Ameer Hamza
Ameer Hamza el 11 de Mzo. de 2020
Bjorn, good that you mentioned it, I didn't know this. Can you point to an example of such a scenario?
Bjorn Gustavsson
Bjorn Gustavsson el 11 de Mzo. de 2020
The simplest example (straigh off the cuff) is gyration of electrically charged particles in a static homogeouns magnetic field - i.e. particle accelerated by a force:
Only one of the odeNM functions were close to conserving the particle energy and and gyro-radius, the other ones had either rather bad growth or loss of kinetic energy.
This is rather understandable, the odeNM cannot know excplicityl what constants of motion there should be - we might implement the equations of motion as coupled first-order ODEs in rather arbitrary order of the components of position and velocity.

Iniciar sesión para comentar.

Más respuestas (1)

Bjorn Gustavsson
Bjorn Gustavsson el 11 de Mzo. de 2020
First thing you should learn/revise/refresh is how to convert higher-order ODEs to sets of coupled first-order ODEs.
You have an equation of motion (well it might be something completely different, but...)
By noting that and , you can convert your second-order ODE to two coupled first-oder ODEs:
Now you have your equation in a format suitable for numerical integration with the odeNN-suite (starting with ode45 I think is the knee-jerk recommendation). To do that you write a function returning a vector with the left-hand-side of the two equations above as a function of time t and v and x. Something like this:
function dxdtdvdt = my_eq_o_motion(t,xv)
x = xv(1);
v = xv(2);
acceleration = % whatever you need for the acceleration as a function of x v and t
dxdtdvdt = [v;acceleration];
end
HTH

Categorías

Más información sobre Programming en Help Center y File Exchange.

Etiquetas

Productos

Community Treasure Hunt

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

Start Hunting!

Translated by