# Inverted order of numpy array gradient and matplotlib quiver

I'm using numpy 1.6 and matplotlib 1.1.1, trying to generate a velocity field from a scalar field that I have. So far, I'm generating my scalar data as such:

``````    num_samples = 50
dim_x = np.linspace(self.min_x, self.max_x,num_samples)
dim_y = np.linspace(self.min_y, self.max_y,num_samples)
X, Y = np.meshgrid(dim_x, dim_y)

len_x = len(dim_x)
len_y = len(dim_y)

a = np.zeros([len_x, len_y], dtype=float)
for i, y in enumerate(dim_y):
for j, x in enumerate(dim_x):
a[i][j] = x*y # not exactly my function, just an example
``````

``````   (velx,vely) =  np.gradient(a)
``````

From the numpy documentation, velx is the x component and vely is the y component of the vector field. Checking the docs for matplotlib, I use quiver to plot a vector field using arrows. It states that velx and vely are the x component and y component of the vector field:

``````    fig0 = plt.figure()
Q = ax.quiver(X,Y, velx, vely )
plt.show()
``````

This gives the wrong result for the velocity field:

The only way of the graph looks ok is if I invert the components on quiver:

``````    Q = ax.quiver(X,Y, vely, velx )#WHY???
``````

I'm suspecting that is something like row-or-column ordering, but I can't figure it out if the output of np.gradient is inverted, or if quiver is inverted. All one dimensional problems are working as expected. Thanks!

EDIT: just to make even more clear how this is inverted, change the function

``````a[i][j] = x*y
``````

to

``````a[i][j] = x*x
``````

The gradient should be in the x direction, increasing with increasing x. The results are still wrong: if I use

``````Q = ax.quiver(X,Y, velx, vely )
``````

I get

and if I invert it

``````Q = ax.quiver(X,Y, vely, velx )
``````

I get

Maybe there's a more pythonic (and correct!) way to do it...

-

I think you're right, (this is an array ordering issue). `a` is built as `a[yidx,xidx]` but when you take the gradient, you do: `velx, vely = np.gradient(a)` when you should be doing `vely, velx = np.gradient(a)`. Since the gradient along the 0th axis should give you `vely` (presumably `d/dy(a) = vely`)? -- unless I'm missing something (in which case I'll happily delete this answer).

Also note that I think you can build "`a`" without the nested lists:

``````a = X*Y
``````

which should work for more complicated functions as well...

-
Thanks for the answer! Could you please explain how I'm building my array as a[yidx, xidx]? I thought that index j, in the second for, is for the row, so x values, and vice versa? If you're right them I should invert the order in the loop, but them this gives problems with contour and contourf... –  Ivan Aug 16 '12 at 19:16
@Ivan -- Simple. In your loops, `i` is returned when iterating over `dim_y` and `j` is returned in your iteration over `dim_x`. Then you pack the elements in as `a[i,j]`. Am I missing something (it's entirely possible). –  mgilson Aug 16 '12 at 19:20
You're totally right. I'm making a huge confusion with the order of the elements. I'm completely confused by what should be x == i or y ==j. –  Ivan Aug 16 '12 at 20:04
@ivan -- Generally, I've stopped thinking about `rows` and `columns`. Those are terms which apply to matrices. you have a 2D array, not a matrix. For me, it's easiest to associate a given dimension with a particular axis. By this, I mean that as I iterate over that axis, I will get slices where the axis value is constant. I'm not sure if that description is helpful or not ... (If it isn't, just ignore this comment). –  mgilson Aug 16 '12 at 20:08