# Determine position in front of 3D plane (cartesian math)

I have a planar element in 3D space that I've rotated on the x, y and z axis. I'm positioning a 3D camera in front of the planar but I need to find a way to calculate the x, y, z of the camera.

I'm trying to figure out how to place the camera at x distance from the planes face. There's obviously a bit of trig involved but for the life of me can't figure it out. Gah.

Dave

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If you have a plane then you also have its normal vector N and some point on it P.
If you calculate `P'=P+x*N` you'll get the point `P'` which is x units infront of point P in the direction of the normal.

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Hmmmmm. Ok, interesting. Not understanding it 100%, refer to my comment for John W. for a better explanation of what I mean. I'm pretty sure in order to solve this the equation would need to factor in the rotation of the plane to make sure it's facing it correctly. – David Sep 22 '09 at 23:27
David, yes. Shoosh's answer is a vector equation. P', P, and N are vectors. x is a scalar. The unit vector's components are a direct result of the orientation of the plane. – John Sep 22 '09 at 23:33
Ok, but being the non-math-focused I am I need to understand how to code these values. The Wolfram article is very helpful in explaining the process, but the math is beyond me. So how could I produce an x, y, z to position the camera from that equation? My guess would be that I have to simply replace N with the vector value. – David Sep 22 '09 at 23:57
"being the non-math-focused" is not an excuse for lazyness. get some decent vector arithmetic book and figure out just exactly it is you want to do. – shoosh Sep 23 '09 at 9:15

The relation between distance of a point to a plane is

distance = (Aa + Bb + Cc + D) / sqrt(A^2+B^2+C^2)

for distance to plane Ax + By + Cz + D = 0 from point (a,b,c)

Might need to multiply by -1 to get distance positive.

The equations for the line through point (a,b,c) perpendicular to the same plane is

x = a + At; y = b + Bt; z = c + Ct

So if you have a point in the plane, you can find the equation of the line perpendicular to that plane. Then you can use the distance constraint to solve for two points a distance along that line - one above the plane, and one below.

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Sorry, that's confused me dramatically. Excuse my ill-math skills but if you could simplify/clarify for me it would be helpful. Lets say the planar is at A (493, 543, 234) - these x, y, z values are referencing from the centre of the plane - and I want the camera positions at 500 units from that point. The planars rotation is x = 34, y = 54, z = 32. So I'd like to find out what point B (?, ?, ?) - the camera - is according to the planars rotation. My best guess was to triangulate a point from the planes four vertices (which I for this case will specify as being 400 width). – David Sep 22 '09 at 23:15
mathworld.wolfram.com/Plane.html – John Sep 22 '09 at 23:29
I don't understand. What is A? What is "the planar?" Are x, y, and z in degrees? What is the sense of the rotation? It sounds like you have a finite sheet, not a plane (which is infinite). Is this true? – John Sep 23 '09 at 0:18
Lets just follow this equation because it's making more sense than what I wrote in the above comment. If you can help me solve this John I'll award you the answer :-) Lets say my normal vector is N = (400, 500, 600) and my P = (405, 505, 605) I would then calculate my P' by doing this: Camera coords: x = Px + x * Nx y = Py + x * Ny z = Pz + x * Nz I'm I getting this right now? lol...or completely off? – David Sep 23 '09 at 0:23
OK, we have progress. :) The point in the plane is P = (Px,Py,Pz). Your normal vector needs to have magnitude 1, so divide each component of N by sqrt(400^2 + 500^2 + 600^2) which is about 877, so N = (Nx,Ny,Nz) is about (400/877, 500/877, 600/877). You said you wanted a distance 500 from this point. So then with P' = (Px',Py',Pz'), we have Px' = Px + 500*Nx, Py' = Py + 500*Ny, Pz' = Pz + 500*Nz. Make more sense? – John Sep 23 '09 at 1:30