Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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

Then I get the gradient:

   (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()
    ax = fig0.add_subplot(111)
    Q = ax.quiver(X,Y, velx, vely )
    plt.show()

This gives the wrong result for the velocity field:

Wrong result for the scalar 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???

Right result with the "wrong" expression

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

Still wrong

and if I invert it

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

I get

Right

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

share|improve this question

1 Answer 1

up vote 1 down vote accepted

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...

share|improve this answer
    
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.