I am tying to figure out how to plot the tidal force vectors on a 3d sphere in python. However, I have no clue where to begin.

A good example of what I am trying to achieve is figure 5 Tides in colliding galaxies

I know how to make a 3d sphere using `matplotlib`

but putting the vectors on it is where I am lost. Additionally, I tried using the potentials giving on page about Tides in Colliding Galaxies but my plots in `Mathematica`

aren't even looking close.

I usually work it in Mathematica when I don't know where to start first.

**EDIT**

I found this code mayavi example

Would there be a way to adapt this for the Earth-Moon system and have the tidal force bulges?

Parameters for Earh-Moon if it can be done

mass earth `5.937 * 10 ** 24`

mass moon `7.348 * 10 ** 22`

distance between the earth and the moon `384400`

earth radius `6371`

moon radius `1737`

```
#!/usr/bin/env python
import numpy as np
import pylab as plt
from mayavi import mlab
from scipy.optimize import newton
def roche(r, theta, phi, pot, q):
lamr, nu = r * np.cos(phi) * np.sin(theta), np.cos(theta)
return (pot - (1.0 / r + q * ( 1.0 / np.sqrt(1. - 2 * lamr + r ** 2) - lamr)
+ 0.5 *(q + 1) * r ** 2 * (1 -nu ** 2)))
theta, phi = np.mgrid[0:np.pi:75j, -0.5 * np.pi:1.5 * np.pi:150j]
pot1, pot2 = 2.88, 10.0
q = 0.5
r_init = 1e-5
r1 = [newton(roche, r_init, args = (th, ph, pot1, q)) for th, ph in
zip(theta.ravel(), phi.ravel())]
r2 = [newton(roche, r_init, args = (th, ph, pot2, 1.0 / q)) for th, ph in
zip(theta.ravel(), phi.ravel())]
r1 = np.array(r1).reshape(theta.shape)
r2 = np.array(r2).reshape(theta.shape)
x1 = r1 * np.sin(theta) * np.cos(phi)
y1 = r1 * np.sin(theta) * np.sin(phi)
z1 = r1 * np.cos(theta)
x2 = r2 * np.sin(theta) * np.cos(phi)
y2 = r2 * np.sin(theta) * np.sin(phi)
z2 = r2 * np.cos(theta)
rot_angle = np.pi
Rz = np.array([[np.cos(rot_angle), -np.sin(rot_angle), 0],
[np.sin(rot_angle), np.cos(rot_angle),0],
[0, 0, 1]])
B = np.dot(Rz, np.array([x2, y2, z2]).reshape((3, -1)))
# we need to have a 3x3 times 3xN array
x2, y2, z2 = B.reshape((3, x2.shape[0], x2.shape[1]))
# but we want our original shape back
x2 += 1 # simple translation
mlab.figure()
mlab.mesh(x1, y1, z1, scalars = r1)
mlab.mesh(x2, y2, z2, scalars = r2)
```

codeyou tried. People here are happy to help you fix code you already have, but are much less interested in writing code for you. – tcaswell Apr 28 '13 at 19:57