# How do I draw an ellipse with SVG, based around a focal point instead of the center?

I'm drawing planetary orbits around a star with SVG, and I need to draw an ellipse that's based around one focal point, rather than the geometric center. I'm drawing it in 2d, but the position needs to take into account the rotation of the ellipse around the focal point, as well as the inclination to the Z axis.

I already have planets that follow the orbital paths, but I can's seem to draw the underlying ellipses so they match up. I have all the orbital data, including all rotational parameters, semi-major, and semi-minor axes. I know I have all the data I need, I just can't seem to figure out how to put it together. Please help!

Here's a diagram of the orbital components: http://upload.wikimedia.org/wikipedia/commons/thumb/e/eb/Orbit1.svg/400px-Orbit1.svg.png

## Example orbit data

``````name: Mercury
semi-major axis (AU): 0.387098
eccentricity: 0.205630
longitude of ascending node (deg): 48.331
inclination (deg): 7.005
argument of perihelion (deg): 29.124
``````

I need the focal point to be at 0,0. By calculating the semi-minor axis ( ry = 0.387098*sqrt(1 - 0.205630^2) ), I can make the ellipse the right shape like this:

``````<ellipse cx="0" cy="0" rx="0.387098" ry="0.378826" />
``````

I can also center the focal point at 0,0 by calculating the distance between the center and the focal point ( cx = sqrt(0.387098^2 - 0.378826^2) ), so I have this:

``````<ellipse cx="0.079597" cy="0" rx="0.387098" ry="0.378826" />
``````

I can't figure out how to rotate the ellipse around point 0,0. I can use the longitude of the ascending node to rotate clockwise around the geometrical center, but I also need to rotate the ellipse in the Z direction with the inclination as well, which will affect the rx and ry values. I also think the argument of perihelion may fit in here as well, but I'm not sure where.

I know the values are less than one, but I'll enlarge everything by using a multiplier once I figure out the process.

### Update:

Thanks to BigBadaboom I can now rotate the ellipse around the focal point. I still need to figure out how to rotate it in 3d. As best as I can figure out, these are the steps:

1. Translate the focal point to 0,0 - done
2. Rotate along the z-axis (2d rotation) by the argument of perihelion (29.124deg) - done (thanks BigBadaboom)
3. Rotate along the y-axis (3d rotation) by the inclination (7.005deg) - ???
4. Rotate along the z-axis again by the longitude of the ascending node (48.331deg) - same process as step 2.

All rotations are centered at 0,0.

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Perhaps my post on Standard form of ellipse can be of some use. Although you don't have the input description that post assumes, so it can only be a small part of a solution. – MvG Oct 17 '13 at 22:21
I haven't heard of eigenvectors before. Can you post a diagram or something? – MrK Oct 18 '13 at 0:57

I'm not sure I quite understand all of what you are trying to do. But you can perform the rotation about 0,0 like this:

``````<ellipse cx="0.079597" cy="0" rx="0.387098" ry="0.378826" transform="rotate(<angle> 0 0)"/>
``````
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Yep, but that only rotates the ellipse around the center. I need to rotate the ellipse around one focal point. That's one tricky part. The other is that I have to rotate it in 3 dimensions. – MrK Oct 18 '13 at 17:36
Ok, I see. You can specify the center of the transform with the rotate parameter. – MrK Oct 18 '13 at 17:42

This probably comes a bit too late, but I was struggling with the same issues myself and ran into this question trying to find some solutions.

I don't think SVGs support 3D rotations, but you could use CSS3 transform instead.

Here is an SVG example I made with the CSS transformations.

For cleaner SVG without CSS browser prefixes (-webkit, -moz etc.) see here. In this version at least Chrome will fail to render the 3D transformations and the orbits in the SVG probably look a bit like in your version before step 3.

You can use url parameters for other variations of the SVG file:

• size: number –> Size of the SVG in pixels
• bbox: number –> Size of the bounding box in AU (1-200)
• noPrefixes –> Don't inlude CSS browser prefixes

For example: `solar.svg?size=800&bbox=160&noPrefixes`

For me the next steps will be calculating the orbits and actual planet locations based on TLE data. In the current version the planets are in random locations on their orbits and of course the orbits are not that accurate either.

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And btw. here's the data I used for the SVG in case you're interested. – jp1 Mar 20 '14 at 10:14
Updates: Now the planets are on their actual positions as of J2000 (1st of Jan 2000). The implementation now ignores all dwarf planets except Pluto. – jp1 Mar 20 '14 at 16:46