# How to improve Brownian motion monte carlo simulation speed?

I want to make my code run faster for more iterations and runs. Right now my code is too slow, but I don't know what to change to speed it up. I began by coding a kinetic Monte Carlo simulation, then editing it to become a Brownian motion simulation. My current code can't handle 10,000 runs with 10,000 iteration each, which is needed.

import numpy as np
import matplotlib.pyplot as plt
import time
%matplotlib inline

runs = int(input("Enter number of runs: "))
N = int(input("Enter number of iterations per simulation: "))

y = 0
R = 10*1  # R is the rate value
t0 = time.time()
for y in range(runs):  # Run the simulation 'runs' times
T = np.array([0])
dt = 0
x = 0.5  # sets values
X = np.array([x])
t = 0
i = 0

while t < N:  # N is the number of iterations per run
i = i + 1  # i is number of iterations so far
z = np.random.uniform(-1, 1, 1)  # sets z to be a random number between -1 to 1 size 1

if z > (1/3):  # if conditions for z for alpha and gamma, beta
x = x + 1  # z[]=alpha state then + 1
elif z < (-1/3):
x = x-1  # z[]=gamma state then - 1
elif z < (1/3) and z > (-1/3):
x = x  # z=beta state then + 0

X = np.append(X, x)  # adds new X value to original X array
X[i] += X[i-1] * 0.01 * np.random.normal(0, 1, 1) * np.sqrt(dt)  # for Brownian motion with sigma as 0.01
Z = np.random.uniform(0, 1)  # sets Z to be a random number between 0 and 1
dt = 1/R * np.log(1/Z)  # formula for dt; R is the rate value
t = t + dt  # ITERATED TIME
T = np.append(T, t)
plt.plot(T, X, lw='0.5', alpha=0.5)

t1 = time.time()
print("final %.10f seconds " % (t1-t0))
• Please edit your code (indentations mostly) to make sure we interpret it correctly – Tacratis Mar 15 at 21:45
• Note: it’d help if you switched to descriptive variable names. Anyway, does plt.plot need to be in the inner loop? Seems like it could go after. Also, T doesn’t look like it needs to be an np.array, so keep T = [] and use T.append(t). Another thing is it looks like NumPy is being used on single elements for the most part which is not what it’s fast at; you may as well use the standard library. – Ry- Mar 15 at 21:45
• Strive to vectorize your code. Instead of e.g. 10,000 runs of single-valued simulations (your z is a single number), have a vector of 10,000 simulations. – John Coleman Mar 15 at 21:46
• @Ry it is in the inner loop to plot multiple graphs on to the same plot, as I will need to show that mean of the plots as we increase the runs the mean should approach 0. – pythonnewbie22 Mar 15 at 21:51
• @pythonnewbie22: It looks like you’re plotting the same plot over itself with one new item each time though. Seems like it should be in the outer loop, after the inner loop. – Ry- Mar 15 at 21:52