# find the distance between a point and a curve python

How can I find the closet distance between my trajectory and `(384400,0,0)`?

Also, how can I the distance from `(384400,0,0)` to the path at time `t = 197465`?

I understand that the arrays have the data but is there a way to have it check the distance of all the points `(x,y,z)` and return what I am looking for?

``````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()
``````
-

To find the distance along each point in the trajectory:

``````my_x, my_y, my_z = (384400,0,0)

delta_x = x - my_x
delta_y = y - my_y
delta_z = z - my_z
distance = np.sqrt(np.power(delta_x, 2) +
np.power(delta_y, 2) +
np.power(delta_z, 2))
``````

And then to find the min and that specific distance:

``````i = np.argmin(distance)
t_min = i / UNITS_SCALE  # I can't tell how many units to a second. Is it 1.6?
d_197465 = distance[int(197465 * UNITS_SCALE)]
``````

PS, I'm no rocket scientist, and thus haven't actually checked the stuff above `x, y, z, x2, y2, z2 = u.T`. I'm assuming that those are your trajectory's position and velocity?

-
the speed changes at different positions so there is no set time per distance. – dustin Apr 23 '13 at 0:20
yes those are the positions and velocities. – dustin Apr 23 '13 at 0:29
how could we put distance into an array? Then we could just ask for the min of an array to be returned. – dustin Apr 23 '13 at 1:12
`distance` is a numpy array. `argmin` asks for the position of the min (The operations are all element-wise). My comment was about your units of time. Your `dt` array goes up to 32,000 but the comment states that it corresponds to 20,000 seconds. In that case, `UNITS_SCALE = 1.6` – Felipe Apr 24 '13 at 4:23
I was able to figure it all out. That is why I accepted your solution. – dustin Apr 24 '13 at 4:25