How to solve and plot second order differential equation using ode45?

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Studentguy am 23 Nov. 2023

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https://de.mathworks.com/matlabcentral/answers/2051187-how-to-solve-and-plot-second-order-differential-equation-using-ode45

Kommentiert: Fabio Freschi am 23 Nov. 2023

Hey there

Im trying to solve and plot the following differential equation using ode45

x''=(-2k*x-2c*x'-r*omega*(cos(omega*t)+(r/L)*cos(2*omega*t))*m+x0*M)/M+m

where

M = 22

m = 0.9

k = 25000

c = 2

omega = 860

L = 0.2

r = 0.07

The starting conditions are :

x0=0

x'0=0

I've tried a bunch of different tutorials, but keep getting different error messages.

Any help is greatly appreciated, thank you!

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Dyuman Joshi am 23 Nov. 2023

Is the value of x0 that appears in the ODE the same as the value of x0 that is one of the initial conditions?

Also, you have defined the variable x_speed in the ODE function, but have not used it. Is there any particular use of that variable?

Studentguy am 23 Nov. 2023

Ye, x0 is the same, its just part the equation i arrived at during calculations.

No x_speed isnt used anywhere.

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Fabio Freschi am 23 Nov. 2023

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https://de.mathworks.com/matlabcentral/answers/2051187-how-to-solve-and-plot-second-order-differential-equation-using-ode45#answer_1358522

Bearbeitet: Fabio Freschi am 23 Nov. 2023

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In your code there is a mistake in the definition of x(1) and x(2)

I have made a few stylistic changes (parameters outside the function, use of implicit function) and the correction of the equations. In addition, I suggest to let ode45 to choose the timestep and keep the t vector provided as output for the plot

% clear variables, close all

x0 = [0 0];

tspan = [0 10];

% params

M = 22;

m = 0.9;

k = 25000;

c = 2;

omega = 860;

l = 0.2;

r = 0.07;

x0_speed = 0;

x0_pos = 0;

% implicit function

% changes here

% | |

% V V

dxdt = @(t,x)[x(2); (-2*k*x(1)-2*c*x(2)-r*omega^2*(cos(omega*t)+(r/l)*cos(2*omega*t))*m+x0_pos*(M-m))/M];

[t,x] = ode45(dxdt,tspan,x0);

figure

plot(t,x)

figure

plot(t,x)

xlim([0 0.5])

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Sam Chak am 23 Nov. 2023

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Hi @Studentguy

I double-check. The original 2nd-order differential equation in your question

is slightly different from the state equation you defined in your code:

( - 2*k*x(1) - 2*c*x(2) - r*omega^2*( cos(omega*t) + (r/l)*cos(2*omega*t) )*m + x0_pos*(M - m) )/M;

Please clarify!

Fabio Freschi am 23 Nov. 2023

This is why I wrote my code according to the orignal equation (as stated in the comment)

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