I was implementing a weighting system called TF-IDF on a set of 42000 images, each consisting 784 pixels. This is basically a 42000 by 784 matrix.

The first method I attempted made use of explicit loops and took *more than 2 hours*.

```
def tfidf(color,img_pix,img_total):
if img_pix==0:
return 0
else:
return color * np.log(img_total/img_pix)
...
result = np.array([])
for img_vec in data_matrix:
double_vec = zip(img_vec,img_pix_vec)
result_row = np.array([tfidf(x[0],x[1],img_total) for x in double_vec])
try:
result = np.vstack((result,result_row))
# first row will throw a ValueError since vstack accepts rows of same len
except ValueError:
result = result_row
```

The second method I attempted used numpy matrices and *took less than 5 minutes*. Note that `data_matrix`

, `img_pix_mat`

are both 42000 by 784 matrices while `img_total`

is a scalar.

```
result = data_matrix * np.log(np.divide(img_total,img_pix_mat))
```

**I was hoping someone could explain the immense difference in speed**.

The authors of the following paper entitled "The NumPy array: a structure for eﬃcient numerical computation" (http://arxiv.org/pdf/1102.1523.pdf), state on the top of page 4 that they observe a 500 times speed increase due to vectorized computation. I'm presuming much of the speed increase I'm seeing is due to this. However, I would like to go a step further and ask why `numpy`

vectorized computations are that much faster than standard python loops?

Also, perhaps you guys might know of other reasons why the first method is slow. Do try/except structures have high overhead? Or perhaps forming a new `np.array`

for each loop is takes a long time?

Thanks.