Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# How to optimize time-stepping algorithm in python?

I have a piece of code which increments a time-step for the so-called Lorenz95 model (invented by Ed Lorenz in 1995). It's normally implemented as a 40-variable model, and displays chaotic behaviour. I have coded up the time-stepping for the algorithm as follows:

``````class Lorenz:
'''Lorenz-95 equation'''

global F, dt, SIZE
F = 8
dt = 0.01
SIZE = 40

def __init__(self):
self.x = [random.random() for i in range(SIZE)]

def euler(self):
'''Euler time stepping'''
newvals = [0]*SIZE
for i in range(SIZE-1):
newvals[i] = self.x[i] + dt * (self.x[i-1] * (self.x[i+1] - self.x[i-2]) - self.x[i] + F)
newvals[SIZE-1] = self.x[SIZE-1] + dt * (self.x[SIZE-2] * (self.x[0] - self.x[SIZE-3]) - self.x[SIZE-1] + F)
self.x = newvals
``````

This function euler is not slow, but unfortunately, my code needs to make a very large number of calls to it. Is there a way I could code the time-stepping to make it run faster?

Many thanks.

-
What the heck is `global` doing in there? – Francis Avila May 8 '13 at 15:44
You could unroll the `for` loop and spell out the series of computations it does -- but there's no getting around the fact that they each have to be done. Might want to consider writing a C extension to do the actual number crunching. – martineau May 8 '13 at 16:14
As we all know the use of `global` is a sign of lazy programming. ;-) I want to make sure that all instances of the class `Lorenz` have the same size for their data array. So, forcing `SIZE` to be a global in this class is the easiest way of ensuring this. – Neill Bowler May 9 '13 at 8:20

There are at least two kinds of possible optimizations: working in a smarter way (algorithmic improvements) and working faster.

• In the algorithmic side, you're using the Euler method, which is a first-order method (so global error is proportional to the step size) and has a smallish stability region. That is, it's not very efficient.

• In the other side, if you're using the standard CPython implementation this kind of code is going to be quite slow. To get around that, you could simply try running it under PyPy. Its Just-in-Time compiler can make numerical code run maybe 100x faster. You could also write a custom C or Cython extension.

But there's a better way. Solving systems of ordinary differential equations is quite common, so scipy, one of the core scientific libraries in Python wraps fast, battle-tested Fortran libraries to solve them. By using scipy, you get both the algorithmic improvemnts (as integrators will have a higher order) and a fast implementation.

Solving the Lorenz 95 model for a set of perturbated initial conditions looks like this:

``````import numpy as np

def lorenz95(x, t):
return np.roll(x, 1) * (np.roll(x, -1) - np.roll(x, 2)) - x + F

if __name__ == '__main__':
import matplotlib.pyplot as plt
from scipy.integrate import odeint
SIZE = 40
F = 8
t = np.linspace(0, 10, 1001)
x0 = np.random.random(SIZE)
for perturbation in 0.1 * np.random.randn(5):
x0i = x0.copy()
x0i[0] += perturbation
x = odeint(lorenz95, x0i, t)
plt.plot(t, x[:, 0])
plt.show()
``````

And the output (setting `np.random.seed(7)`, yours can be different) is nicely chaotic. Small perturbations in the initial conditions (in just one of he coordinates!) produce very different solutions:

But, is it really faster than Euler time stepping? For `dt = 0.01` it seems almost three times faster, but the solutions don't match except at the very beginning.

If `dt` is reduced, the solution provided by the Euler method gets increasingly similar to the `odeint` solution, but it takes much longer. Notice how the smaller dt, the later Euler solutions loose track of the `odeint` solution. The most precise Euler solution took 600x longer to computed the solution up to t=6 than odeint up to t=10. See the full script here.

In the end, this system is so unstable that I guess not even the odeint solution is accurate along all plotted time.

-
Thanks @jorgeca for the suggestions. Your code makes a couple of important changes: 1. The use of `np.roll` means that the whole array can be updated in a single sweep, so I now have a new Euler time-stepping scheme: `def euler2(self): self.x = self.x + dt * (np.roll(self.x, 1) * (np.roll(self.x, -1) - np.roll(self.x, 2)) - self.x + F)`. This is around 3 times faster than the original implementation. 2. The use of `odeint`, rather than a crude Euler time-step. This maybe more stable, but is quite a bit slower (2 times slower than the Euler routine). I guess I shall have to use compiled code. – Neill Bowler May 9 '13 at 15:02
@NeillBowler The faster results from your Euler routine are spurious except at the very very beginning. I'll expand my answer maybe tomorrow to show you that, but the summary is "to achieve the same error in the solution, Euler time stepping will take way many orders of magnitude more time than odeint". – jorgeca May 9 '13 at 19:52
@NeillBowler I've expanded the answer. – jorgeca May 11 '13 at 21:42
Many thanks for your great response. I've looked into the accuracy of the solver. Most papers using this model (including the [journals.ametsoc.org/doi/abs/10.1175/… paper)) use a Runge-Kutta fourth-order scheme with a time-step of 0.05. I've tested this with compiled code and found that RK4 with time-step 0.01 is pretty accurate. `odeint` can be more accurate, but slower and reducing the solver tolerance doesn't make it much faster, esp when using many calls (as I have to) rather than one large call (as in your code) – Neill Bowler May 13 '13 at 15:44
@NeillBowler You're welcome! It's a rather cool system and I didn't know about it. Maybe you are interested in `scipy.integrate.ode`, which lets you choose a RK45 for instance, and doesn't return the whole solution. Instead, you get to call `.integrate(time)`, which may be better suited for whatever you're doing. (PS: there's a small typo in your link, I'm not sure if you'll be able to edit it). – jorgeca May 13 '13 at 18:16