Here is a little script I wrote for making fractals using newton's method.

```
import numpy as np
import matplotlib.pyplot as plt
f = np.poly1d([1,0,0,-1]) # x^3 - 1
fp = np.polyder(f)
def newton(i, guess):
if abs(f(guess)) > .00001:
return newton(i+1, guess - f(guess)/fp(guess))
else:
return i
pic = []
for y in np.linspace(-10,10, 1000):
pic.append( [newton(0,x+y*1j) for x in np.linspace(-10,10,1000)] )
plt.imshow(pic)
plt.show()
```

I am using numpy arrays, but nonetheless loop through each element of 1000-by-1000 linspaces to apply the `newton()`

function, which acts on a single guess and not a whole array.

My question is this: **How can I alter my approach to better exploit the advantages of numpy arrays?**

P.S.: If you want to try the code without waiting too long, better to use 100-by-100.

Extra background:

See Newton's Method for finding zeroes of a polynomial.

The basic idea for the fractal is to test guesses in the complex plane and count the number of iterations to converge to a zero. That's what the recursion is about in `newton()`

, which ultimately returns the number of steps. A guess in the complex plane represents a pixel in the picture, colored by the number of steps to convergence. From a simple algorithm, you get these beautiful fractals.