# Create dataset of XYZ positions on a given plane

I need to create a list of XYZ positions given a starting point and an offset between the positions based on a plane. On just a flat plane this is easy. Let's say the offset I need is to move down 3 then right 2 from position 0,0,0

The output would be:

``````0,0,0 (starting position)
0,-3,0 (move down 3)
2,-3,0 (then move right 2)
``````

The same goes for a different start position, let's say 5,5,1:

``````5,5,1 (starting position)
5,2,1 (move down 3)
7,2,1 (then move right 2)
``````

The problem comes when the plane is no longer on this flat grid.

I'm able to calculate the equation of the plane and the normal vector given 3 points. But now what can I do to create this dataset of XYZ locations given this equation?

I know I can solve for XYZ given two values. Say I know x=1 and y=1, I can solve for Z. But moving down 2 is no longer just y-2. I believe I need to find a linear equation on both the x and y axis to increment the positions and move parallel to the x and y of this new plane, then just solve for Z. I'm not sure how to accomplish this.

The other issue is that I need to calculate the angle, tilt and rotation of this plane in relation to the base plane.

For example:

``````P1=0,0,0 and P2=1,1,0 the tilt=0deg angle=0deg rotation=45deg.
P1=0,0,0 and P2=0,1,1 the tilt=0deg angle=45deg rotation=0deg.
P1=0,0,0 and P2=1,0,1 the tilt=45deg angle=0deg rotation=0deg.
P1=0,0,0 and P2=1,1,1 the tilt=0deg angle=45deg rotation=45deg.
``````

I've searched for hours on both these problems and I've always come to a stop at the equation of the plane. Manipulating the x,y correctly to follow parallel to the plane, and then taking that information to find these angles. This is a lot of geometry to be solved, and I can't find any further information on how to calculate this list of points, let alone calculating the 3 angles to the base plane.

I would appericate any help or insight on this. Just plain old math or a reference to C++ would be perfect to sheding some light onto this issue I'm facing here.

Thank you, Matt

-
Hi there! Just wanted to clarify some things - what do you mean by "up" "down" "left" and "right" in a context that is no longer 2D? I think that is the root cause of your confusion. When you say "down", do you now mean 3 units in the opposite direction of the (+) normal vector to the plane? or 3 units in the -z_hat direction? If you clarify this, the rest becomes quite simple. –  im so confused Sep 13 '12 at 18:10
The other thing I wanted to clarify was what you mean by "tilt" "angle" and "rotation". There are many ways of producing a new orientation of a rigid body, but generally people think of Euler Angles as their rotation operations. (there are others such as Roll Pitch Yaw - Tait Bryant, etc) –  im so confused Sep 13 '12 at 18:14
Akshaya, I can see how there is no reference to up,down,left,right. What I'd like to do is move parallel to the sides of the plane. Here's a crappy paint image to illustrate this Plane Image. So from P1 I want to move parallel to S1 to the point in blue. Then move parallel to S2 to the point in green. –  Matt Sep 13 '12 at 18:51

You can think of your plane as being defined by a point and a pair of orthonormal basis vectors (which just means two vectors of length 1, 90 degrees from one another). Your most basic plane can be defined as:

``````p0 = (0, 0, 0) #Origin point
vx = (1, 0, 0) #X basis vector
vy = (0, 1, 0) #Y basis vector
``````

To find point `p1` that's offset by `dx` in the X direction and `dy` in the Y direction, you use this formula:

``````p1 = p0 + dx * vx + dy * vy
``````

This formula will always work if your offsets are along the given axes (which it sounds like they are). This is still true if the vectors have been rotated - that's the property you're going to be using.

So to find a point that's been offset along a rotated plane:

1. Take the default basis vectors (`vx` and `vy`, above).
2. Rotate them until they define the plane you want (you may or may not need to rotate the origin point as well, depending on how the problem is defined).
@Matt - No problem. Say you've got three points: `p1`, `p2`, and `p3`. Pick any one of them to use as `p0` - I'll pick `p2`. subtract that point from the other two to get your vectors: `v1 = p1 - p2` and `v2 = p3 - p2`. To get an orthonormal basis from those, you can use the Gram-Schmidt Process. Sadly, though, this is plagued by the same ambiguity as the point + normal version: you don't know how the plane is rotated relative to its normal. If you'd chosen a different point as `p0`, you'd have gotten a different basis. –  Xavier Holt Sep 13 '12 at 19:57