# Solving a differential equation in parallel, python

I am numerically solving a differential equation that depends on parameters. I am not really interested on the solutions but on their behaviour depending on the value of the parameters. Since I want a very precise description I must use a very fine array of parameters' values resulting in a lot of ODE solving processes. So I want to know if it would be possible to "parallelize" such a program. The idea is that maybe each processor of my computer can solve the ODE for a distinct pair of parameters. A kind of example is the following:

``````import matplotlib.pyplot as plt
from scipy.integrate import ode
import numpy as np

# - ODE - #
def sys(t,x,p1,p2): #p1 and p2 are the parameters
dx=np.zeros(2)
dx[0] = x[1]
dx[1] = (p1+p2*cos(t))*x[0]
return dx

t0=0; tEnd=10; dt=0.01
r = ode(sys).set_integrator('dopri5', nsteps=10,max_step=dt)
Y=[];S=[];T=[]
ic=[.1,0]
# - parameters range - #
P1=np.linspace(0,1,100)
P2=np.linspace(0,1,100)
# -------------------- #
for p1 in P1:
for p2 in P2:
r.set_initial_value(ic, t0).set_f_params(p1,p2)
flag='No'
while r.successful() and r.t +dt < tEnd:
r.integrate(r.t+dt)
Y.append(r.y)
T.append(r.t)
#-This is what we want to know.
if r.y[0]>2*ic[0]:
flag='Yes'
break
if flag=='Yes':
plt.scatter(p1,p2,s=1, c='k', marker='.')
# ------------------------------------ #
plt.show()
``````

Note that each `for` loop is independent so: Is it possible to make those `for` loops in a parallel way? So I would imagine that it is possible that each of my 8 processors do one double `for` loop at a time and then probably make the computations roughly 8 times faster? Or at least faster?

-
Take a look at the queue module –  kalhartt Oct 4 '13 at 14:43
Thanks, I checked it, but I found also dispy which solves my problem just as I wanted, I thought on answering my own question but It seems it is not possible, at least for me. –  PepeToro Nov 1 '13 at 18:49
@user58533 I think you have enough reputation points now to answer your own question. I think it'd be of interest seeing any more detail to your solution :) –  Steve Koch Jan 13 '14 at 22:29