Numerically solve a 3rd order differential equation with 3 unknowns

7 views (last 30 days)

Show older comments

Raffaele on 1 Jun 2023

0
Link

Direct link to this question

https://www.mathworks.com/matlabcentral/answers/1976859-numerically-solve-a-3rd-order-differential-equation-with-3-unknowns

Commented: Torsten on 3 Jun 2023

Accepted Answer: Torsten

Open in MATLAB Online

Hi, I have a 3rd order differential equation in y, with 3 unknowns a, b, c. To simplify imagine the equation is:

diff(y, t, 3) + a.*diff(y, t, 2) + b.*diff(y, t) + y.^(3/2) + c.*y == 0;

I know the discrete values of y and the time vector. I want to know tha values of a, b, c that solve this equation. Clearly there will be more combination of this values, but is there a way to solve it? (like with ode function or others).

One idea would be to express all the derivatives as function of y (like using finite differences) and then solve, is there a way to do it automatically on matlab?

2 Comments
Show NoneHide None

Sam Chak on 1 Jun 2023

Hi @Raffaele

Can you confirm if the data pair

is absolutely governed by the dynamics?

Raffaele on 2 Jun 2023

Edited: Raffaele on 2 Jun 2023

Actually the dynamic is more complicated, because there are also multiplications and divisions of the unknown parameters and also combination with other known parameters (like mass, spring stiffness, ecc.), like shown in my answer below. I just wrote that equation to simplify the presentation of the problem.

Accepted Answer

Torsten on 1 Jun 2023

0
Link

Direct link to this answer

https://www.mathworks.com/matlabcentral/answers/1976859-numerically-solve-a-3rd-order-differential-equation-with-3-unknowns#answer_1248574

Edited: Torsten on 1 Jun 2023

Open in MATLAB Online

Use "gradient" three times to get approximations for y', y'' and y''' in the points of your t-vector.

Let diff_y, diff_y2, diff_y3 be these approximations as column vectors of length n.

Now form a matrix A as

A = [diff_y2,diff_y,y]

and a column vector v as

v = [-y.^(3/2) - diff_y3]

Then approximations for a, b and c can be obtained using

sol = A\v

with

a = sol(1)
b = sol(2)
c = sol(3)

12 Comments
Show 10 older commentsHide 10 older comments

Raffaele on 3 Jun 2023

Thank you, so now I try to insert it in an lsqnonlin to find the best option for a, b, c

Torsten on 3 Jun 2023

For the lsqnonlin fitting procedure, you can try two ways:

The first is without using the ode integrator and generating y',y'' and y''' from your data by using the "gradient" function.

The second is with the ode integrator by integrating the differential equation for given parameters a, b and c and by comparing the result with your given data for y.

Products

MATLAB

Release

R2021b

Community Treasure Hunt

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

Start Hunting!