ODEs with infinite initlal condition in python

I have a second order differential equation that I want to solve it in python. The problem is that for one of the variables I don't have the initial condition in `0` but only the value at infinity. Can one tell me what parameters I should provide for `scipy.integrate.odeint` ? Can it be solved?

Equation:

Theta needs to be found in terms of time. Its first derivative is equal to zero at `t=0`. theta is not known at `t=0` but it goes to zero at sufficiently large time. all the rest is known. As an approximate `I` can be set to zero, thus removing the second order derivative which should make the problem easier.

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You can find the answer from this question stackoverflow.com/questions/1824751/… – user1929959 Jan 20 '13 at 16:28
What is your equation? – Jaime Jan 20 '13 at 17:05
@Jaime, equation added. – rowman Jan 20 '13 at 19:07
You cannot give `scipy.integrate.odeint` conditions at two different values of `t`. If instead of a second condition at infinity, you had it at `t = t1`, you could nest your solution with `scipy.integrate.odeint` inside a call to `scipy.optimize.root` to find the value of tetha at `t = 0` that gave you the desired behavior at `t = t1`. Maybe choosing a large enough `t1` would allow you to use that idea. You may also want to try scicomp.stackexchange.com for help figuring the right strategy to tackle your problem. – Jaime Jan 21 '13 at 8:09
@Jaime, Could you please provide a rough answer by using `scipy.optimize.root` and predicting `t1` value? – rowman Jan 21 '13 at 20:35

This is far from being a full answer, but is posted here on the OP's request.

The method I described in the comment is what is known as a shooting method, that allows converting a boundary value problem into an initial value problem. For convenience, I am going to rename your function `theta` as `y`. To solve your equation numerically, you would first turn it into a first order system, using two auxiliary function, `z1 = y` and `z2 = y'`, and so your current equation

``````I y'' + g y' + k y = f(y, t)
``````

would be rewitten as the system

``````z1' = z2
z2' = f(z1, t) - g z2 - k z1
``````

``````z1(inf) = 0
z2(0) = 0
``````

So first we set up the function to compute the derivative of your new vectorial function:

``````def deriv(z, t) :
return np.array([z[1],
f(z[0], t) - g * z[1] - k * z[0]])
``````

If we had a condition `z1[0] = a` we could solve this numerically between `t = 0` and `t = 1000`, and get the value of `y` at the last time as something like

``````def y_at_inf(a) :
return scipy.integrate.odeint(deriv, np.array([a, 0]),
np.linspace(0, 1000, 10000))[0][-1, 0]
``````

So now all we need to know is what value of `a` makes `y = 0` at `t = 1000`, our poor man's infinity, with

``````a = scipy.optimize.root(y_at_inf, [1])
``````
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