Given two rotational angles, how do I calculate an orbital position?

I'm moving around a satellite around another object in 3D space by adjusting two rotational angles - rotation about the X and Y axes of the tracked object. How do I calculate the objects final position given those angles and a radius?

This works fine for just the y-axis rotation:

``````position.x = otherObject.position.x + Math.cos(yRotation) * radius;
position.y = otherObject.position.y;
position.z = otherObject.position.z + Math.sin(yRotation) * radius;
``````

But as soon as I try and incorporate the x-axis rotation, things get weird.

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You can rotate something in 2D using these equations (see Wikipedia):

``````x' = x * cos(angle) - y * sin(angle)
y' = x * sin(angle) + y * cos(angle)
``````

You can use basically the same equations for rotating about the x/y/z axes in 3D, eg for rotating about the y axis:

``````x' = x * cos(angle) - z * sin(angle)
y' = y
z' = x * sin(angle) + z * cos(angle)
``````

I think what you want to do is:

• Rotate by yRotation about the y axis
• Then rotate by xRotation about the x axis

You've already done the y axis rotation. So starting with (x, y, z) = (radius, 0, 0), you've done:

``````x' = x * cos(angley) - z * sin(angley) = radius * cos(angley)
y' = y = 0
z' = x * sin(angley) + z * cos(angley) = radius * sin(angley)
``````

We just have to apply the equations again to rotate about the x axis:

``````x'' = x' = radius * cos(angley)
y'' = y' * cos(anglex) - z' * sin(anglex) = -radius * sin(angley) * sin(anglex)
z'' = y' * sin(anglex) + z' * cos(anglex) = radius * sin(angley) * cos(anglex)
``````

Note that adjusting the "y axis" rotation won't necessarily rotate the satellite about the y axis (eg if your x rotation is 90 degrees, then adjusting the y rotation will actually rotate about the z axis). If you don't like this behaviour, I would suggest just storing the satellite (x, y, z) (relative to the tracked object) and adjusting that directly (you'll probably want to re-normalise after each adjustment to ensure floating point inaccuracy doesn't make your satellite drift away).

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Am I understanding you correct if I think you're saying the calculations should be: position.x = otherObject.position.x + Math.cos(yRotation) * radius; position.y = otherObject.position.y - Math.sin(yRotation) * Math.sin(xRotation); position.z = otherObject.position.z + Math.sin(yRotation) * Math.cos(xRotation) * radius; ? If so, that doesn't work either. I can post the full code somewhere if that helps to understand the problem. –  korona Jun 5 '12 at 6:17
Correction: position.x = otherObject.position.x + Math.cos(yRotation) * radius; position.y = otherObject.position.y - Math.sin(yRotation) * Math.sin(xRotation) * radius; position.z = otherObject.position.z + Math.sin(yRotation) * Math.cos(xRotation) * radius; Still doesn't work... –  korona Jun 5 '12 at 6:26
@korona Yes, that's what I was saying. I struggle to see why that "doesn't work" -- I believe it's essentially the same as the solution you've posted, with a couple of minor differences: yours starts with (x, y, z) = (0, 0, radius) rather than (radius, 0, 0); yours rotates by x first (you're doing outv = RY * RX * inv); your x rotation is in the opposite direction. –  dave Jun 5 '12 at 17:22
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