# Convert Latitude and Longitude to point in 3D space

I need to convert latitude and longitude values to a point in the 3-dimensional space. I've been trying this for about 2 hours now, but I do not get the correct results.

The Equirectangular coordinates come from openflights.org. I've tried several combinations of cos and sin, but the result did never look like our little beloved earth.

In the following, you can see the result of applying the conversion Wikipedia suggests. I think one can guess from context what `c4d.Vector` is.

``````def llarToWorld(latit, longit, altid, rad):
x = math.sin(longit) * math.cos(latit)
z = math.sin(longit) * math.sin(latit)
y = math.cos(longit)
v = c4d.Vector(x, y, z)
v = v * altid + v * rad
return v
``````

Red: X, Green: Y, Blue: Z

One can indeed identify North- and South America, especially the land around the Gulf of Mexico. However, it looks somewhat squished and kind of in the wrong place..

As the result looks somewhat rotated, I think, I tried swapping latitude and longitude. But that result is somewhat awkward.

``````def llarToWorld(latit, longit, altid, rad):
temp = latit
latit = longit
longit = temp
x = math.sin(longit) * math.cos(latit)
z = math.sin(longit) * math.sin(latit)
y = math.cos(longit)
v = c4d.Vector(x, y, z)
v = v * altid + v * rad
return v
``````

This is what the result looks like without converting the values.

``````def llarToWorld(latit, longit, altid, rad):
return c4d.Vector(math.degrees(latit), math.degrees(longit), altid)
``````

Question: How can I convert the longitude and latitude correctly?

## Solution

Thanks to TreyA, I found this page on mathworks.com. The code that does it's work is the following:

``````def llarToWorld(lat, lon, alt, rad):
# see: http://www.mathworks.de/help/toolbox/aeroblks/llatoecefposition.html
f  = 0                              # flattening
ls = atan((1 - f)**2 * tan(lat))    # lambda

x = rad * cos(ls) * cos(lon) + alt * cos(lat) * cos(lon)
y = rad * cos(ls) * sin(lon) + alt * cos(lat) * sin(lon)
z = rad * sin(ls) + alt * sin(lat)

return c4d.Vector(x, y, z)
``````

Actually, I switched `y` and `z` because the earth was rotated then, however, it works! That's the result:

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`altid` is the altitude, but what is `rad`? Is that the radius of earth? Are `altid` and `rad` in the same units (feet)? What if you only use the radius (i.e. just `v = v * rad`)? – Omri Barel May 6 '12 at 20:58
also look at googling 'lla to ecef' - latitude/longitude/altitude to earth-centered earth-fixed. – TreyA May 7 '12 at 11:59
@TreyA Perfect, thank you! Found this: mathworks.de/help/toolbox/aeroblks/llatoecefposition.html It is the correct formula. :) You can make your comment an answer if you want the rep, and this way I can also mark my question as answered. – Niklas R May 9 '12 at 13:25

you're not doing what wikipedia suggests. read it again carefully.

they say:

``````x = r cos(phi) sin(theta)
y = r sin(phi) sin(theta)
z = r cos(theta)
``````

and then:

``````theta == latitude
phi == longitude
``````

so you should be using:

``````r = radius + altitude
x = r cos(long) sin(lat)
y = r sin(long) sin(lat)
z = r cos(lat)
``````

note that the final entry is `cos(lat)` (you are using longitude).

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Unfortunately that is the same result as pixture #2 shows.. :( – Niklas R May 9 '12 at 13:25
no it's not. lat/long are swapped only for z. you swapped them all. – andrew cooke May 9 '12 at 13:59
Well, it's not exactly the same, but equals very much the second picture. And it's very much equal to the first picture when swapping lat and long. The link I found by searching `lla to ecef` (Thanks to TreyA) is perfect. See: mathworks.de/help/toolbox/aeroblks/llatoecefposition.html – Niklas R May 9 '12 at 14:33

I've reformatted the code that was previously mentioned here, but more importantly you have left out some of the equations mentioned in the link provided by Niklas R

``````def LLHtoECEF(lat, lon, alt):
# see http://www.mathworks.de/help/toolbox/aeroblks/llatoecefposition.html

f = np.float64(1.0/298.257223563)  # Flattening factor WGS84 Model
cosLat = np.cos(lat)
sinLat = np.sin(lat)
FF     = (1.0-f)**2
C      = 1/np.sqrt(cosLat**2 + FF * sinLat**2)
S      = C * FF

x = (rad * C + alt)*cosLat * np.cos(lon)
y = (rad * C + alt)*cosLat * np.sin(lon)
z = (rad * S + alt)*sinLat

return (x, y, z)
``````

Comparison output: finding ECEF for Los Angeles, CA (34.0522, -118.40806, 0 elevation)
My code:
X = -2516715.36114 meters or -2516.715 km
Y = -4653003.08089 meters or -4653.003 km
Z = 3551245.35929 meters or 3551.245 km

X = -2514072.72181 meters or -2514.072 km
Y = -4648117.26458 meters or -4648.117 km
Z = 3571424.90261 meters or 3571.424 km

Although in your earth rotation environment your function will produce right geographic region for display, it will NOT give the right ECEF equivalent coordinates. As you can see some of the parameters vary by as much as 20 KM which is rather a large error.

Flattening factor, `f` depends on the model you assume for your conversion. Typical, model is WGS 84; however, there are other models.

Personally, I like to use this link to Naval Postgraduate School for sanity checks on my conversions.

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This works but you first need to convert angles to radians. And lat/long values are usually supplied as degrees. – Tomislav Muic Apr 5 '14 at 14:41

As TreyA statet, `LLA to ECEF` is the solution. See http://www.mathworks.de/help/toolbox/aeroblks/llatoecefposition.html

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