# create plane with 3d points

The following code defines the normal vector and the radius of the plane in order to visualize it.My question is about `d` and offset. Is `d` the D from the plane equation `Ax+By+Cz+D=0` (Because I must give a `d` and I don't find one with that code)? The code will help me define if a 3D point is above/down, in front/behind, left/right of a plane. Any feedback that would help me understand this is much appreciated.

``````**function [fixture,n,min_radius] = planePointPoint(p1,p2,p3,q,d,varargin)**

% p1, p2 and p3 -3d points that define an oriented plane.
%q is the point that is tested against this plane
% p1+offset is the fixture point for the plane.
% d is the offset distance for the plane in the direction of n.
% optional argument offset is a 3-vector denoting an offset to be added to the fixture point during min_radius calculation
%
% function returns sequence of fixture points and unit normals along with
% minimum radii that make sense to visualize position of q in relation to the plane.
offset = [0;0;0];
if (nargin>6)
offset = varargin{1};
end
n = cross(p1 - p3,p2 - p3);%defines normal vector
n = n./repmat(sqrt(sum(n.^2)),3,1);%normalise  normal vector
offset = repmat(offset,1,mot.nframes) -   repmat(dot(n,repmat(offset,1,mot.nframes)),3,1).*n;
%points = p1 + n*d;
fixture = p1+offset  + n*d;
dist_q = dot(n,q-fixture);
dist_p1 = dot(n,p1-fixture);
dist_p2 = dot(n,p2-fixture);
dist_p3 = dot(n,p3-fixture);
q_proj = q - repmat(dist_q,3,1).*n;
p1_proj = p1 - repmat(dist_p1,3,1).*n;
p2_proj = p2 - repmat(dist_p2,3,1).*n;
p3_proj = p3 - repmat(dist_p3,3,1).*n;
``````
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I don't understand exactly what this code is doing, but it does seem that `d` (which is used in the line `fixture = p1+offset + n*d;`) must be the signed distance between the origin and the plane defined by the three points. If you describe your plane by the equation `Ax+By+Cz+D=0`, with `(A,B,C)` being the normal unit vector `n` described in the code, then `d = - D`.

If this is correct, then whoever wrote this code was particularly evil to ask `d` from the caller, since it can be computed from the other inputs:

``````d = dot(n,p1);
``````

Concerning your actual problem (`The code will help me define if a 3D point is above/down, in front/behind, left/right of a plane.`), simply use these two lines:

``````n = cross(p1 - p3,p2 - p3);
h = dot(n,q-p1);
``````

If `h` is null then `q` belongs to the plane, if it is positive then it is above the plane, and if it is negative then it is below. Here, "above" means that if you look at the plane from `q`, then the sequence `p1`->`p2`->`p3`->`p1` is cycling counter-clockwise.

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Thank you for your response.that is what i believe too.i can't understand why to ask d from the user.Basically the code is to animate the plane , so i think that it finds the max radius in order to create an disc to animate the plane.I use the same code of yours to define where an arbirtary 3d point is, relative to the plane. –  pap-00 Sep 10 '13 at 13:34
I found that D is the signed distance from the origin if normal vector is normalised.Because i use the code for skeleton motion, can d in the code defined from the user as a threshold?? for example d= 2*length of humerus in a skeleton. Furthermore fixture in the code , means that i transfer the origin in a point of the plane?? thank you again Boris for your answer –  pap-00 Sep 10 '13 at 13:38
Hi again @pap-00. I am afraid that I will not be able to help you on this one. Without more context, I cannot guess what the variables are suppose to mean, and anyway even if I had this information, it would take me a significant amount of time that I can't afford :-) You'll have to figure it out by yourself now. If you still can't make sense of it, contact other users of the library, or the author of the library, only them would have an answer. –  Boris Sep 10 '13 at 17:59
hi boris.you've right.thank you anyway! –  pap-00 Sep 12 '13 at 13:57