EDIT: Wow, I've just realised this question is more than 3 years old. I'll still leave my answer hoping it finds its way to someone in the same predicament. Sorry for that.
I had the same problem. I was able to parallelise such process as follows.
First you need dispy. In there you'll find some programs that will do the paralelization process for you. I am not an expert on
dispybut I had no problems using it, and I didn't need to configure anything.
So, how to use it?
python dispynode.py -d. If you do not run this script before running your main program, the parallel jobs won't be performed.
Run your main program. Here I post the one I used (sorry for the mess). You'll need to change the function
sim, and change accordingly to what you want to do with the results. I hope however that my program works as a reference for you.
import os, sys, inspect
#Add dispy to your path
cmd_folder = os.path.realpath(os.path.abspath(os.path.split(inspect.getfile( inspect.currentframe() ))))
if cmd_folder not in sys.path:
# use this if you want to include modules from a subforder
cmd_subfolder = os.path.realpath(os.path.abspath(os.path.join(os.path.split(inspect.getfile( inspect.currentframe() )),cmd_folder+"/dispy-3.10/")))
if cmd_subfolder not in sys.path:
#This function contains the differential equation to be simulated.
def sim(ic,e,O): #ic=initial conditions; e=Epsiolon; O=Omega
from scipy.integrate import ode
import numpy as np
p = 2.*e*O*np.sin(O*t)*(1-e*np.cos(O*t))/(z+(1-e*np.cos(O*t))**2)
q = (1+4.*b/l*np.cos(O*t))*(z+(1-e*np.cos(O*t)))/( z+(1-e*np.cos(O*t))**2 )
dx = x
dx = -q*x-p*x
t0=0; tEnd=10000.; dt=0.1
r = ode(sys).set_integrator('dop853', nsteps=10,max_step=dt) #Definition of the integrator
# - parameters - #
z=0.5; l=1.0; b=0.06;
# -------------- #
r.set_initial_value(ic, t0).set_f_params(e,O,z,b,l) #Set the parameters, the initial condition and the initial time
#Loop to integrate.
while r.successful() and r.t +dt < tEnd:
if r.y>1.25*ic: #Bound. This is due to my own requirements.
#r.y contains the solutions and r.t contains the time vector.
return e,O,color #For each pair e,O return e,O and a color (0,1) which correspond to the color of the point in the stability chart (0=unstable) (1=stable)
# ------------------------------------ #
#MAIN PROGRAM where the parallel magic happens
import matplotlib.pyplot as plt
import numpy as np
F=100 #Total files
#Range of the values of Epsilon and Omega
Epsilon = np.linspace(0,1,100)
Omega_intervals = np.linspace(0,4,F)
cluster = dispy.JobCluster(sim) #This function sets that the cluster (array of processors) will be assigned the job sim.
jobs =  #Initialize the array of jobs
for i in range(F-1):
jobs = 
for e in Epsilon:
for O in Omega:
job = cluster.submit(ic,e,O) #Send to the cluster a job with the specified parameters
jobs.append(job) #Join all the jobs specified above
#Do the jobs
for job in jobs:
e,O,color = job()
#Save the results of the simulation.