Compute divergence of vector field using python

Question

Is there a function that could be used for calculation of the divergence of the vectorial field? (in matlab) I would expect it exists in numpy/scipy but I can not find it using Google.

I need to calculate div[A * grad(F)], where

F = np.array([[1,2,3,4],[5,6,7,8]]) # (2D numpy ndarray)

A = np.array([[1,2,3,4],[1,2,3,4]]) # (2D numpy ndarray)

so grad(F) is a list of 2D ndarrays

I know I can calculate divergence like this but do not want to reinvent the wheel. (I would also expect something more optimized) Does anyone have suggestions?

Answer 1

Just a hint for everybody reading that:

the functions above do not compute the divergence of a vector field. they sum the derivatives of a scalar field A:

result = dA/dx + dA/dy

in contrast to a vector field (with three dimensional example):

result = sum dAi/dxi = dAx/dx + dAy/dy + dAz/dz

Vote down for all! It is mathematically simply wrong.

Cheers!

Answer 2

import numpy as np

def divergence(field):
    "return the divergence of a n-D field"
    return np.sum(np.gradient(field),axis=0)

Answer 3

Based on Juh_'s answer, but modified for the correct divergence of a vector field formula

def divergence(f):
    """
    Computes the divergence of the vector field f, corresponding to dFx/dx + dFy/dy + ...
    :param f: List of ndarrays, where every item of the list is one dimension of the vector field
    :return: Single ndarray of the same shape as each of the items in f, which corresponds to a scalar field
    """
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[i], axis=i) for i in range(num_dims)])

Matlab's documentation uses this exact formula (scroll down to Divergence of a Vector Field)

Answer 4

The answer of @user2818943 is good, but it can be optimized a little:

def divergence(F):
    """ compute the divergence of n-D scalar field `F` """
    return reduce(np.add,np.gradient(F))

---

Timeit:

F = np.random.rand(100,100)
timeit reduce(np.add,np.gradient(F))
# 1000 loops, best of 3: 318 us per loop

timeit np.sum(np.gradient(F),axis=0)
# 100 loops, best of 3: 2.27 ms per loop

About 7 times faster: sum implicitely construct a 3d array from the list of gradient fields which are returned by np.gradient. This is avoided using reduce

---

Now, in your question what do you mean by div[A * grad(F)]?

1. about A * grad(F): A is a 2d array, and grad(f) is a list of 2d arrays. So I considered it means to multiply each gradient field by A.
2. about applying divergence to the (scaled by A) gradient field is unclear. By definition, div(F) = d(F)/dx + d(F)/dy + .... I guess this is just an error of formulation.

For 1, multiplying summed elements Bi by a same factor A can be factorized:

Sum(A*Bi) = A*Sum(Bi)

Thus, you can get this weighted gradient simply with: A*divergence(F)

If ̀A is instead a list of factor, one for each dimension, then the solution would be:

def weighted_divergence(W,F):
    """
    Return the divergence of n-D array `F` with gradient weighted by `W`

    ̀`W` is a list of factors for each dimension of F: the gradient of `F` over
    the `i`th dimension is multiplied by `W[i]`. Each `W[i]` can be a scalar
    or an array with same (or broadcastable) shape as `F`.
    """
    wGrad = return map(np.multiply, W, np.gradient(F))
    return reduce(np.add,wGrad)

result = weighted_divergence(A,F)

Answer 5

What Daniel had modified is the right answer, let me explain self defined func divergence further in more detail :

Function np.gradient() defined as : np.gradient(f) = df/dx, df/dy, df/dz +...

but we need define func divergence as : divergence ( f) = dfx/dx + dfy/dy + dfz/dz +... = np.gradient( fx) + np.gradient(fy) + np.gradient(fz) + ...

Let's test, compare with example of divergence in matlab

import numpy as np
import matplotlib.pyplot as plt

NY = 50
ymin = -2.
ymax = 2.
dy = (ymax -ymin )/(NY-1.)

NX = NY
xmin = -2.
xmax = 2.
dx = (xmax -xmin)/(NX-1.)

def divergence(f):
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[i], axis=i) for i in range(num_dims)])

y = np.array([ ymin + float(i)*dy for i in range(NY)])
x = np.array([ xmin + float(i)*dx for i in range(NX)])

x, y = np.meshgrid( x, y, indexing = 'ij', sparse = False)

Fx  = np.cos(x + 2*y)
Fy  = np.sin(x - 2*y)

F = [Fx, Fy]
g = divergence(F)

plt.pcolormesh(x, y, g)
plt.colorbar()
plt.savefig( 'Div' + str(NY) +'.png', format = 'png')
plt.show()

---------- UPDATED VERSION: Include the differential Steps----------------

Thank the comment from @henry, the np.gradient take the default step as 1, so the results may have some mismatch. We can provide our own differential steps.

#https://stackoverflow.com/a/47905007/5845212
import numpy as np
import matplotlib.pyplot as plt
from mpl_toolkits.axes_grid1 import make_axes_locatable

NY = 50
ymin = -2.
ymax = 2.
dy = (ymax -ymin )/(NY-1.)

NX = NY
xmin = -2.
xmax = 2.
dx = (xmax -xmin)/(NX-1.)


def divergence(f,h):
    """
    div(F) = dFx/dx + dFy/dy + ...
    g = np.gradient(Fx,dx, axis=1)+ np.gradient(Fy,dy, axis=0) #2D
    g = np.gradient(Fx,dx, axis=2)+ np.gradient(Fy,dy, axis=1) +np.gradient(Fz,dz,axis=0) #3D
    """
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[i], h[i], axis=i) for i in range(num_dims)])

y = np.array([ ymin + float(i)*dy for i in range(NY)])
x = np.array([ xmin + float(i)*dx for i in range(NX)])

x, y = np.meshgrid( x, y, indexing = 'ij', sparse = False)

Fx  = np.cos(x + 2*y)
Fy  = np.sin(x - 2*y)

F = [Fx, Fy]
h = [dx, dy]



print('plotting')
rows = 1
cols = 2
#plt.clf()
plt.figure(figsize=(cols*3.5,rows*3.5))
plt.minorticks_on()


#g = np.gradient(Fx,dx, axis=1)+np.gradient(Fy,dy, axis=0) # equivalent to our func
g = divergence(F,h)
ax = plt.subplot(rows,cols,1,aspect='equal',title='div numerical')
#im=plt.pcolormesh(x, y, g)
im = plt.pcolormesh(x, y, g, shading='nearest', cmap=plt.cm.get_cmap('coolwarm'))
plt.quiver(x,y,Fx,Fy)
divider = make_axes_locatable(ax)
cax = divider.append_axes("right", size="5%", pad=0.05)
cbar = plt.colorbar(im, cax = cax,format='%.1f')


g = -np.sin(x+2*y) -2*np.cos(x-2*y)
ax = plt.subplot(rows,cols,2,aspect='equal',title='div analytical')
im=plt.pcolormesh(x, y, g)
im = plt.pcolormesh(x, y, g, shading='nearest', cmap=plt.cm.get_cmap('coolwarm'))
plt.quiver(x,y,Fx,Fy)
divider = make_axes_locatable(ax)
cax = divider.append_axes("right", size="5%", pad=0.05)
cbar = plt.colorbar(im, cax = cax,format='%.1f')


plt.tight_layout()
plt.savefig( 'divergence.png', format = 'png')
plt.show()

Answer 6

Based on @paul_chen answer, and with some additions for Matplotlib 3.3.0 (a shading param needs to be passed, and default colormap I guess has changed)

import numpy as np
import matplotlib.pyplot as plt

NY = 20; ymin = -2.; ymax = 2.
dy = (ymax -ymin )/(NY-1.)
NX = NY
xmin = -2.; xmax = 2.
dx = (xmax -xmin)/(NX-1.)

def divergence(f):
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[i], axis=i) for i in range(num_dims)])

y = np.array([ ymin + float(i)*dy for i in range(NY)])
x = np.array([ xmin + float(i)*dx for i in range(NX)])

x, y = np.meshgrid( x, y, indexing = 'ij', sparse = False)

Fx  = np.cos(x + 2*y)
Fy  = np.sin(x - 2*y)


F = [Fx, Fy]
g = divergence(F)

plt.pcolormesh(x, y, g, shading='nearest', cmap=plt.cm.get_cmap('coolwarm'))
plt.colorbar()
plt.quiver(x,y,Fx,Fy)
plt.savefig( 'Div.png', format = 'png')

Answer 7

The divergence as a built-in function is included in matlab, but not numpy. This is the sort of thing that it may perhaps be worthwhile to contribute to pylab, an effort to create a viable open-source alternative to matlab.

http://wiki.scipy.org/PyLab

Edit: Now called http://www.scipy.org/stackspec.html

Answer 8

As far as I can tell, the answer is that there is no native divergence function in numpy. Therefore, the best method for calculating divergence is to sum the components of the gradient vector i.e. calculate the divergence.

Answer 9

I don't think the answer by @Daniel is correct, especially when the input is in order [Fx, Fy, Fz, ...].

A simple test case

See the MATLAB code:

a = [1 2 3;1 2 3; 1 2 3];
b = [[7 8 9] ;[1 5 8] ;[2 4 7]];
divergence(a,b)

which gives the result:

ans =

   -5.0000   -2.0000         0
   -1.5000   -1.0000         0
    2.0000         0         0

and Daniel's solution:

def divergence(f):
    """
    Daniel's solution
    Computes the divergence of the vector field f, corresponding to dFx/dx + dFy/dy + ...
    :param f: List of ndarrays, where every item of the list is one dimension of the vector field
    :return: Single ndarray of the same shape as each of the items in f, which corresponds to a scalar field
    """
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[i], axis=i) for i in range(num_dims)])


if __name__ == '__main__':
    a = np.array([[1, 2, 3]] * 3)
    b = np.array([[7, 8, 9], [1, 5, 8], [2, 4, 7]])
    div = divergence([a, b])
    print(div)
    pass

which gives:

[[1.  1.  1. ]
 [4.  3.5 3. ]
 [2.  2.5 3. ]]

Explanation

The mistake of Daniel's solution is, in Numpy, the x axis is the last axis instead of the first axis. When using np.gradient(x, axis=0), Numpy actually gives the gradient of y direction (when x is a 2d array).

My solution

There is my solution based on Daniel's answer.

def divergence(f):
    """
    Computes the divergence of the vector field f, corresponding to dFx/dx + dFy/dy + ...
    :param f: List of ndarrays, where every item of the list is one dimension of the vector field
    :return: Single ndarray of the same shape as each of the items in f, which corresponds to a scalar field
    """
    num_dims = len(f)
    return np.ufunc.reduce(np.add, [np.gradient(f[num_dims - i - 1], axis=i) for i in range(num_dims)])

which gives the same result as MATLAB divergence in my test case.

Answer 10

Somehow the previous attempts to compute the divergence are wrong! Let me show you:

We have the following vector field F:

F(x) = cos(x+2y)
F(y) = sin(x-2y)

If we compute the divergence (using Mathematica):

Div[{Cos[x + 2*y], Sin[x - 2*y]}, {x, y}]

we get:

-2 Cos[x - 2 y] - Sin[x + 2 y]

which has a maximum value in the range of y [-1,2] and x [-2,2]:

N[Max[Table[-2 Cos[x - 2 y] - Sin[x + 2 y], {x, -2, 2 }, {y, -2, 2}]]] = 2.938

Using the divergence equation given here:

def divergence(f):
        num_dims = len(f)
        return np.ufunc.reduce(np.add, [np.gradient(f[i], axis=i) for i in range(num_dims)])

we get a maximum value of about 0.625

Correct divergence function: Compute divergence with python