# Convert a 3d drillhole trace to cartesian coordinates and plot it with matplotlib

I would like to be able to plot two lines using direction and distance. It is a Drillhole trace, so I have the data in this format right now,

The depth is actually distance down the hole, not vertical depth. Azimuth is from magnetic north. Dip is based on 0 being horizontal. I want to plot two lines from the same point (0,0,0 is fine) and see how they differ, based on this kind of info.

I have no experience with Matplotlib but am comfortable with Python and would like to get to know this plotting tool. I have found this page and it helped to understand the framework, but I still can't figure out how to plot lines with 3d vectors. Can someone give me some pointers on how to do this or where to find the directions I need? Thank you

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The first step, and probably the biggest challenge, is to find a way to convert this data into cartesian coordinates. Then, you just need to plot them –  goncalopp Dec 19 '13 at 16:52
I was hoping that this was a fairly common task and a module would be available inside matplotlib. I've done this in 2d with shapely, I'll look to see if someone's made a 3d equivalent. –  cndnflyr Dec 19 '13 at 16:54
matplotlib supports polar coordinates, but if I'm reading your explanation correctly, you need to shift your "center" for each point, and perform corrections in the angles, depending on how you want the final result oriented –  goncalopp Dec 19 '13 at 17:01
That's right. Start at 0,0,0. Find the next coordinate that 255.6° on the horizontal plane, 79.5° down from the horizontal plane, and 14 M from 0,0,0. Then from that found coordinate, find the next, etc... –  cndnflyr Dec 19 '13 at 17:04
Check out this Wolfram article on spherical coordinates and conversion to Cartesian. Could be useful... –  MattDMo Dec 19 '13 at 17:04

A script converting your coordinates to cartesian and plotting it with matplotlib with the comments included:

``````import numpy as np
import matplotlib.pyplot as plt
# import for 3d plot
from mpl_toolkits.mplot3d import Axes3D
# initializing 3d plot
fig = plt.figure()
ax = fig.add_subplot(111, projection = '3d')
# several data points
r = np.array([0, 14, 64, 114])
# get lengths of the separate segments
r[1:] = r[1:] - r[:-1]
phi = np.array([255.6, 255.6, 261.7, 267.4])
theta = np.array([-79.5, -79.5, -79.4, -78.8])
phi = phi * 2 * np.pi / 360.
# in spherical coordinates theta is measured from zenith down; you are measuring it from horizontal plane up
theta = (90. - theta) * 2 * np.pi / 360.
# get x, y, z from known formulae
x = r*np.cos(phi)*np.sin(theta)
y = r*np.sin(phi)*np.sin(theta)
z = r*np.cos(theta)
# np.cumsum is employed to gradually sum resultant vectors
ax.plot(np.cumsum(x),np.cumsum(y),np.cumsum(z))
``````
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That is super! Thank you. There is a lot in there. That's slick to do the transformations to all the points and then just add them up to get each coordinate. I'm still wrapping my head around the phi and theta conversions out of polar coordinates. I don't understand how the r[1:] = r[1:] - r[:-1] works though. Could you elaborate? –  cndnflyr Dec 19 '13 at 21:16
@cndnflyr `r[1:] = r[1:] - r[:-1]` is the same as saying [r[n+1] - r[n] for n in range(1,len(r))] -- if that even helps. In words: start at the second element of `r` and redefine each subsequent element as the different between it and the original previous element. –  Paul H Dec 19 '13 at 21:44
@Paul Thank you, that does help. It's using two lists taken out of the original and using the list starting at r[0] to subtract from the list starting at r[1]. Because they are the same length, this works. That's great. –  cndnflyr Dec 19 '13 at 22:02
as a strange side point`r[1:] - r[:-1]` is faster than `np.diff(r)`. –  tcaswell Dec 20 '13 at 5:54
@tcaswell: This might be because of function call overhead - `np.diff` is recursive. –  Andrey Sobolev Dec 20 '13 at 7:15