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This time, it's not really an important question, but maybe an interesting one.

Let us assume we have two variables x ans y. This variables depend on time (a discrete time). We have a starting condition and want to iterate them over time. Let us assume we have x[0] = a and y[0] = b. We now want to calculate all the given points for a small amount of time and we know the following relation between these two variables:

x[n+1] = x[n] + y[n]
y[n+1] = y[n] + np.sin(x[n+1])

Of course we can do it with a loop:

x[0], y[0] = a, b

for n in range(100): # just an arbitrary iteration
    x[n+1] = x[n] + y[n]
    y[n+1] = y[n] + np.sin(x[n+1])

Okay. This is possible, if I didn't make some mistakes =). What I want is maybe to have a much better and more numpy-like way to solve it without an iteration. I tried to come up with some shifting or other stuff. I just want a calculation on the arrays without a loop, cause loops are really boring. I just had an idea with recursive function calls, but I have to try it out tomorrow in the morning.

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3  
This kind of recurrence relation is the prototypical case of something that cannot be written in an efficient vectorised form in NumPy. If speed matters, use a different language, like Cython. Maybe numexpr can optimise this as well, not sure. –  Sven Marnach Apr 2 '12 at 21:56
    
I was thinking that it isn't possible, but wanted to ask anyways. –  PateToni Apr 2 '12 at 22:01
    
using xrange will help if you are going for more than a 100, but ya I think this is exactly the kind of operation you can't do in numpy. You have a ton of typo's. I edited one for you (when you are assigning the 0 variables), but you also used n in stead of i. –  Garrett Berg Apr 10 '12 at 20:01
    
You have written discrete equations. If that is genuinely what you need to solve, then there isn't much else you can do. However, if what you really need is to solve a continuous ODE, then scipy has several routines specifically for this purpose docs.scipy.org/doc/scipy/reference/… –  DaveP Apr 11 '12 at 8:46

1 Answer 1

As the commenters said above, this can't be nicely vectorized. If you want a quick fix that should help with the speed, consider the inline option from scipy.weave. The code below is a script that gives a working example of this for your desired discrete system. This should be much better than a Python for-loop for large arrays.

import scipy.weave as weave
import numpy as np

def simulate_x_and_y(x,y,a,b):

    x[0] = a; y[0] = b;
    n_range = len(x)

    code = """
    #include <math.h>

    for(int n = 1; n < n_range; n++){
        x(n) = x(n-1) + y(n-1);
        y(n) = y(n-1) + sin(x(n)); 
    }
    """

    weave.inline(code, ['x','y','n_range'], 
                 type_converters = weave.converters.blitz,
                 compiler = "gcc", headers=["<math.h>"]
                )


if __name__ == "__main__":

    x = np.zeros(10);
    y = np.zeros(10);
    a = 4.0; b = 10.0;

    print "Before:"
    print x
    print y

    simulate_x_and_y(x,y,a,b)

    print "After:"
    print x
    print y
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