After bashing my head for a while now, I finally got the grips with the difference with row-order that Python uses and the definition of coordinates in a Cartesian plane. It's simple, but I'm putting it here because it can be confusing for the novice or the dyslexic.

As it has been pointed out, this is very similar to the behavior of np.meshgrid. The reason of this question is to explain in plain words the idea of the conversion of a cartesian plane to a matrix form.

Given a plane with a point in the lower left, pos_inf, with coordinates pos_inf = (x_inf, y_inf) and a point in the upper right, pos_sup (x_sup, y_sup), a spacing h (that I assume it will be the same for the x and y directions), the number of discretization points in each direction is equal to

```
points_x = int((x_sup - x_inf) / h)
points_y = int((y_sup - y_inf) / h)
```

Let's say that I want to store the value of a function in each point of this grid. I generate a matrix with size

```
a = np.zeros((points_y, points_x))
```

Note that the rightmost index in Python, j in a[i,j], go through the elements in the the *same* line, points_x times. i, the leftmost index, will go through the number of columns, points_y. A for loop is given by

```
for i in xrange(points_y):
for j in xrange(points_x):
a[i,j] = i
```

This way the points in the direction x are correspondent to the j index, and the points in the y direction are correspondent to the i index. So, for example, if points_x = 5 and points_y = 6, a cartesian space discretized with h = 1, starting with x_inf=0 to x_sup=5 and y_inf = 0 to y_sup = 6, would be

```
a = np.zeros((5,6))
for i in xrange(5):
for j in xrange(6):
a[i,j] = i
array([[ 0., 0., 0., 0., 0., 0.],
[ 1., 1., 1., 1., 1., 1.],
[ 2., 2., 2., 2., 2., 2.],
[ 3., 3., 3., 3., 3., 3.],
[ 4., 4., 4., 4., 4., 4.]])
```

This graph shows the directions:

`np.indices((5,6))`

. – DSM Nov 3 '12 at 22:12