# 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 = fig.add_subplot(111, projection='3d')
ax.plot(x, y, z)
plt.show()
``````
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## 2 Answers

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 at 14:46
your code was good I had an error in mine –  dustin Apr 23 at 17:15
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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 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 at 22:22
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