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I am using NumPy to do some calculation on finding the Y intercept, through an Aperture between a big box and a small box. I have over 100.000 particles in the big box, and around 1000 in the small one. And it's taking a lot of time to do so. All the self.YD, self.XD are very large arrays that i'm multiplying.

PS: The ind are indexes of the values that need to be multiplied. I had a nonzero condition before that line in my code.

Any ideas how I would do this calculation in a simpler way?

YD_zero = self.oldYD[ind] - ((self.oldYD[ind]-self.YD[ind]) * self.oldXD[ind])/(self.oldXD[ind]-self.XD[ind])

Thanks!

UPDATE

Would using multiply, divide, subtract and all that stuff of Numpy. make it faster? Or if maybe if i split the calculation. for example.

to do this first:

    YD_zero = self.oldYD[ind] - ((self.oldYD[ind]-self.YD[ind])*self.oldXD[ind])

and then the next line would be:

    YD_zero /= (self.oldXD[ind]-self.XD[ind])

Any suggestions?!

UPDATE 2

I have been trying to figure this out, in a while now, but not much progress. My concern is that the denominator :

    self.oldXL[ind]-self.XL[ind] == 0

and I am getting some weird results.

The other thing is the nonzero function. I have been testing it for a while now. Could anybody tell me that it is almost the same as find in Matlab

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Is the loss of precision significant if you try trim the sets of points? –  Wok Jul 20 '11 at 16:25
    
I need to have really accurate data. –  Don Code Jul 20 '11 at 16:31
    
By simpler, do you mean in fewer cpu cycles? –  Jonathan M Jul 20 '11 at 16:31
    
I have this inside a while loop, and do it at least 16000 times in one run. So, whatever would make this calculation faster. –  Don Code Jul 20 '11 at 16:32

3 Answers 3

Perhaps I have got the wrong end of the stick but in Numpy you can perform vectorised calculations. Remove the enclosing while loop and just run this ...

YD_zero = self.oldYD - ((self.oldYD - self.YD) * self.oldXD) / (self.oldXD - self.XD)

It should be much faster.

Update: Iterative root finding using the Newton-Raphson method ...

unconverged_mask = np.abs(f(y_vals)) > CONVERGENCE_VALUE:
while np.any(unconverged_mask):
    y_vals[unconverged_mask] = y_vals[unconverged_mask] - f(y_vals[unconverged_mask]) / f_prime(y_vals[unconverged_mask])
    unconverged_mask = np.abs(f(y_vals)) > CONVERGENCE_VALUE:

This code is only illustrative but it shows how you can apply an iterative process using vectorised code to any function f which you can find the derivative of f_prime. The unconverged_mask means that the results of the current iteration will only be applied to those values that have not yet converged.

Note that in this case there is no need to iterate, Newton-Raphson will give you the correct answer in the first iteration since we are dealing with straight lines. What you have is an exact solution.

Second update

Ok, so you aren't using Newton-Raphson. To calculate YD_zero (the y intercept) in one go, you can use,

YD_zero = YD + (XD - X0) * dYdX

where dYdX is the gradient, which seems to be, in your case,

dYdX = (YD - oldYD) / (XD - oldXD)

I am assuming XD and YD are the current x,y values of the particle, oldXD and oldYD are the previous x,y values of the particle and X0 is the x value of the aperture.

Still not entirely clear why you have to iterate over all the particles, Numpy can do the calculation for all particles at once.

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If you vectorize it, it also allows for the ability to later move to the GPU if you really need the speed. –  Abe Schneider Jul 20 '11 at 18:05
    
I did vectorize it, but I have plenty of other things in the loop. I think this is taking longer than everything else. Because I've ran it without this, and it was a lot more faster. –  Don Code Jul 20 '11 at 18:14
1  
I believe the loop is not on the index, but rather for the iterative Newton algorithm. –  Wok Jul 20 '11 at 21:06
    
Ah right, so you are using the Newton-Raphson method to find zeros in a function? If so, the updated code may be of help. –  Brendan Jul 21 '11 at 9:55
    
Also be aware that since we are dealing with straight lines, there is no need to apply the Newton-Raphson equation more than once, it will be correct on the first iteration. –  Brendan Jul 21 '11 at 11:13

Since all the computations are done element-wise, it should be easy to re-write the expression in Cython. This will avoid all those very large temporary array that get created when you do oldYD-YD and such.

Another possibility is numexpr.

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How would I multiply two arrays with Numexpr or Cython?! And would you rather suggest Cython or Numexpr? –  Don Code Jul 20 '11 at 18:15
    
@theSun: What is it specifically about multiplication that's causing confusion? As to Cython vs numexpr, the latter should be easier to get right. However, I personally have only used the former so there could be subtleties around numexpr that I am not aware of. –  NPE Jul 20 '11 at 19:45

I would definitely go for numexpr. I'm not sure numexpr can handle indices, but I bet that the following (or something similar) would work:

import numexpr as ne

yold = self.oldYD[ind]
y = self.YD[ind]
xold = self.oldXD[ind]
x = self.XD[ind]
YD_zero = ne.evaluate("yold - ((yold - y) * xold)/(xold - x)")
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