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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.


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.mesh(x1, y1, z1, scalars = r1)
mlab.mesh(x2, y2, z2, scalars = r2)
share|improve this question
I would suggest mayavi (code.enthought.com/projects/mayavi) instead. MPL specializes in 2D plotting and can do some 3D stuff by generating projections of 3D plots onto 2D, but it has limitations. mayavi, on the other hand, is based an opengl and is designed for 3D plotting from the get-go. –  tcaswell Apr 28 '13 at 17:51
@tcaswell thanks. Do you know how to plot the tidal force vectors? I tried but don't get anything close. –  dustin Apr 28 '13 at 17:57
What have you tried? That example isn't 3D. –  tcaswell Apr 28 '13 at 18:27
@tcaswell I tried plotting the potential and specifying the region grater than the Earth's radius of 6371 KM. –  dustin Apr 28 '13 at 19:09
show us the code you 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

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