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Okay, I have this not so pretty 2nd order non-linear ODE I should be able to solve numerically.

f''(R)+(2/R)f'(R)=(.7/R)((1/sqrt(f))-((0.3)/sqrt(1-f))), f'(0)=1, f(1)=1

I was thinking of breaking this guy up into a system of two first order ODE's and then solve, but I have no idea how to set this up. What method should I use to set up the system of ODE's?

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closed as off topic by Bill the Lizard Mar 22 '13 at 11:04

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If there is some other method rather than numerically solving a system of differential equations, please feel welcome to share. Thanks. –  Shagster_84 Oct 16 '10 at 7:46
If you want to know how to break up a 2nd order ODE, ask in math.stackexchange.com instead. –  KennyTM Oct 16 '10 at 7:57
Thanks for the link! –  Shagster_84 Oct 16 '10 at 8:01

2 Answers 2

The canonical way of breaking up a 2nd order ODE

y''(x) = f(y', y, x)

into 2 1st order ODEs is by introducing a notation

z(x) := y'(x)

and setting up a system

z'(x) = f(z, y, x)

y'(x) = z(x)

with initial conditions z(0) = y'(0) and y(0) given as before. The system of 1st order ODEs can be solved by e.g. Runge-Kutta method.

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you case use laplace transforms to solve a set of second order linear ordinary differential equations . Procedure is as follows Apply L-transforms on both sides to both the differntial eqautions You will end up with two linearalgebraic equations solve them

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Can you please expand on this answer? –  Gordon Mar 22 '13 at 11:03

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