# plotting a sphere in python for an orbital trajectory

How can I put a sphere of radius 1737 at the location of (384400,0,0)?

This sphere would be the moon in my trajectory.

Everything else with the code is fine, I just don't know how to add a sphere in that location with that radius.

import numpy as np
from scipy.integrate import odeint
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d import Axes3D

me = 5.974 * 10 ** (24)  #  mass of the earth
mm = 7.348 * 10 ** (22)  #  mass of the moon
G = 6.67259 * 10 ** (-20)  #  gravitational parameter
re = 6378.0  #  radius of the earth in km
rm = 1737.0  #  radius of the moon in km
r12 = 384400.0  #  distance between the CoM of the earth and moon
M = me + mm

pi1 = me / M
pi2 = mm / M
mue = 398600.0  #  gravitational parameter of earth km^3/sec^2
mum = G * mm  #  grav param of the moon
mu = mue + mum
omega = np.sqrt(mu / r12 ** 3)
nu = -129.21 * np.pi / 180  #  true anomaly angle in radian

x = 327156.0 - 4671
#  x location where the moon's SOI effects the spacecraft with the offset of the
#  Earth not being at (0,0) in the Earth-Moon system
y = 33050.0   #  y location

vbo = 10.85  #  velocity at burnout

gamma = 0 * np.pi / 180  #  angle in radians of the flight path

vx = vbo * (np.sin(gamma) * np.cos(nu) - np.cos(gamma) * np.sin(nu))
#  velocity of the bo in the x direction
vy = vbo * (np.sin(gamma) * np.sin(nu) + np.cos(gamma) * np.cos(nu))
#  velocity of the bo in the y direction

xrel = (re + 300.0) * np.cos(nu) - pi2 * r12
#  spacecraft x location relative to the earth
yrel = (re + 300.0) * np.sin(nu)

#  r0 = [xrel, yrel, 0]
#  v0 = [vx, vy, 0]
u0 = [xrel, yrel, 0, vx, vy, 0]

def deriv(u, dt):
n1 = -((mue * (u[0] + pi2 * r12) / np.sqrt((u[0] + pi2 * r12) ** 2
+ u[1] ** 2) ** 3)
- (mum * (u[0] - pi1 * r12) / np.sqrt((u[0] - pi1 * r12) ** 2
+ u[1] ** 2) ** 3))
n2 = -((mue * u[1] / np.sqrt((u[0] + pi2 * r12) ** 2 + u[1] ** 2) ** 3)
- (mum * u[1] / np.sqrt((u[0] - pi1 * r12) ** 2 + u[1] ** 2) ** 3))
return [u[3],  #  dotu[0] = u[3]
u[4],  #  dotu[1] = u[4]
u[5],  #  dotu[2] = u[5]
2 * omega * u[5] + omega ** 2 * u[0] + n1,  #  dotu[3] = that
omega ** 2 * u[1] - 2 * omega * u[4] + n2,  #  dotu[4] = that
0]  #  dotu[5] = 0

dt = np.arange(0.0, 320000.0, 1)  #  200000 secs to run the simulation
u = odeint(deriv, u0, dt)
x, y, z, x2, y2, z2 = u.T

fig = plt.figure()
ax.plot(x, y, z)
plt.show()
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You can add the following code to draw the sphere, before the plt.show():

phi = np.linspace(0, 2 * np.pi, 100)
theta = np.linspace(0, np.pi, 100)
xm = rm * np.outer(np.cos(phi), np.sin(theta)) + r12
ym = rm * np.outer(np.sin(phi), np.sin(theta))
zm = rm * np.outer(np.ones(np.size(phi)), np.cos(theta))
ax.plot_surface(xm, ym, zm)

However, your moon will look all stretched out because the scale is not equal for all axes. In order to change the scales of the axes, you can add something like

ax.auto_scale_xyz([-50000, 400000], [0, 160000], [-130000, 130000])

before plt.show(). The result is still not completely right, but I leave it up to you to play around to get better results -- I just picked some numbers that make it look somewhat better.

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the moon appears to be well below the curve. Why is it not on the ecliptic plane? –  dustin Apr 23 '13 at 14:46
your code was good I had an error in mine –  dustin Apr 23 '13 at 17:15

All the code for a sphere is here:

http://matplotlib.org/examples/mplot3d/surface3d_demo2.html

From there you just have to shift in whichever direction you want and change the 10 to whatever radius you desire.

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how do I shift it? –  dustin Apr 23 '13 at 2:52
take the expression they gave for x , y, or z and at the end just add whatever you want to shift the sphere by on that respective axis –  menzwearhouse719 Apr 23 '13 at 22:22