# setup odes in python

how to setup the following odes with the corresponding initial conditions in python?

`x'(t) =x(t) - y(t) - e^t`

`y'(t) =x(t) + y(t) + 2e^t`

with `x(0)= -1` and `y(0)= -1` and `0 <= t <= 4`

The following is what I have so far:

``````def f(u, t):
x, y = u
return [x+y-e**t, x+y+2*e**t]

x0, y0 = [-1.0,-1.0]
t = numpy.linspace( 0,4,50 )
``````
-
What are you trying to do? What is the problem? Please be a lot more specific. –  Blubber May 25 '13 at 8:03
Also, you got that `e` defined somewhere? In any case, you should use `math.exp()` for that. –  Blubber May 25 '13 at 8:08
You should use numpy.exp because it's a vectorized version of math.exp (at least in spirit, because numpy.exp is much more efficient ). –  deufeufeu May 25 '13 at 8:38
I don't have any experience with numpy so I'll have to take your word for it :). –  Blubber May 25 '13 at 8:40

I guess you're trying to solve them with odeint. First I'm assuming you use this prelude in you script :

``````import numpy as np
from scipy.integrate import odeint
``````

``````def equation(X, t):
x, y = X
return [ x+y-np.exp(t), x+y+2*np.exp(t) ]
``````

and then you can solve them with

``````init = [ -1.0, -1.0 ]
t = np.linpsace(0, 4, 50)
X = odeint(equation, init, t)
``````

You can extract x(t) and y(t) with

``````x = X[:, 0]
y = X[:, 1]
``````
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The system is already of first-order. You are solving a second order problem in your post. –  David Zwicker May 25 '13 at 9:05
Your post solves the problem `x' = vx; vx' = x+y-exp(t); ...` which is equivalent to `x'' = x+y-exp(t); ...`. Hence, you solve a second order problem by rewriting it as first-order equations. This is also apparent from the fact that your function returns a fourth-dimensional vector. –  David Zwicker May 25 '13 at 9:33
My bad. You're right. I've edited my post. Thank you. –  deufeufeu May 25 '13 at 9:41
You're welcome. –  David Zwicker May 25 '13 at 9:48
OMG : Does it answers your question? –  deufeufeu May 25 '13 at 10:38