# How can I plot a 3D-plane in Matlab?

I would like to plot a plane using a vector that I calculated from 3 points where:

``````pointA = [0,0,0];
pointB = [-10,-20,10];
pointC = [10,20,10];

plane1 = cross(pointA-pointB, pointA-pointC)
``````

How do I plot 'plane1' in 3D?

Here's an easy way to plot the plane using `fill3`:

``````points=[pointA' pointB' pointC']; % using the data given in the question
fill3(points(1,:),points(2,:),points(3,:),'r')
grid on
alpha(0.3)
``````

• `fill3` take `X,Y,Z` as input and not 3 points. Take a look at the plane you drew, it doesn't pass through `(0,0,0)`. You drew a plane that passes through `(0,-10,10)`, `(0, -20,20)` and `(0,10,10)` – Andrey Rubshtein Nov 20 '12 at 12:03
• According to Matlab documentation (2nd line for fill3) "fill3(X,Y,Z,C) fills three-dimensional polygons. X, Y, and Z triplets specify the polygon vertices". I did made a mistake though in the way I input the points to `fill3` (wrong dimension used), and this is now corrected. thanks for noticing. I still think a one liner is nicer than several lines... – bla Nov 20 '12 at 16:24
• That's ok, you got my upvote anyway, I just wanted you to correct the mistake :) – Andrey Rubshtein Nov 20 '12 at 16:29

You have already calculated the normal vector. Now you should decide what are the limits of your plane in `x` and `z` and create a rectangular patch.

An explanation : Each plane can be characterized by its normal vector `(A,B,C)` and another coefficient `D`. The equation of the plane is `AX+BY+CZ+D=0`. Cross product between two differences between points, `cross(P3-P1,P2-P1)` allows finding `(A,B,C)`. In order to find `D`, simply put any point into the equation mentioned above:

``````   D = -Ax-By-Cz;
``````

Once you have the equation of the plane, you can take 4 points that lie on this plane, and draw the patch between them.

``````normal = cross(pointA-pointB, pointA-pointC); %# Calculate plane normal
%# Transform points to x,y,z
x = [pointA(1) pointB(1) pointC(1)];
y = [pointA(2) pointB(2) pointC(2)];
z = [pointA(3) pointB(3) pointC(3)];

%Find all coefficients of plane equation
A = normal(1); B = normal(2); C = normal(3);
D = -dot(normal,pointA);
%Decide on a suitable showing range
xLim = [min(x) max(x)];
zLim = [min(z) max(z)];
[X,Z] = meshgrid(xLim,zLim);
Y = (A * X + C * Z + D)/ (-B);
reOrder = [1 2  4 3];
figure();patch(X(reOrder),Y(reOrder),Z(reOrder),'b');
grid on;
alpha(0.3);
``````
• This doesn't work if B is 0 – Eric Jan 13 '16 at 18:34
• @Eric, true, it should have other cases for zeroes or close to zeroes coefficients. – Andrey Rubshtein Jan 14 '16 at 9:11
• See my answer for another solution – Eric Jan 15 '16 at 17:15

Here's what I came up with:

``````function [x, y, z] = plane_surf(normal, dist, size)

normal = normal / norm(normal);
center = normal * dist;

tangents = null(normal') * size;

res(1,1,:) = center + tangents * [-1;-1];
res(1,2,:) = center + tangents * [-1;1];
res(2,2,:) = center + tangents * [1;1];
res(2,1,:) = center + tangents * [1;-1];

x = squeeze(res(:,:,1));
y = squeeze(res(:,:,2));
z = squeeze(res(:,:,3));

end
``````

Which you would use as:

``````normal = cross(pointA-pointB, pointA-pointC);
dist = dot(normal, pointA)

[x, y, z] = plane_surf(normal, dist, 30);
surf(x, y, z);
``````

Which plots a square of side length 60 on the plane in question

I want to add to the answer given by Andrey Rubshtein, his code works perfectly well except at B=0. Here is the edited version of his code

Below Code works when A is not 0

``````normal = cross(pointA-pointB, pointA-pointC);
x = [pointA(1) pointB(1) pointC(1)];
y = [pointA(2) pointB(2) pointC(2)];
z = [pointA(3) pointB(3) pointC(3)];
A = normal(1); B = normal(2); C = normal(3);
D = -dot(normal,pointA);
zLim = [min(z) max(z)];
yLim = [min(y) max(y)];
[Y,Z] = meshgrid(yLim,zLim);
X = (C * Z + B * Y + D)/ (-A);
reOrder = [1 2  4 3];
figure();patch(X(reOrder),Y(reOrder),Z(reOrder),'r');
grid on;
alpha(0.3);
``````

Below Code works when C is not 0

``````normal = cross(pointA-pointB, pointA-pointC);
x = [pointA(1) pointB(1) pointC(1)];
y = [pointA(2) pointB(2) pointC(2)];
z = [pointA(3) pointB(3) pointC(3)];
A = normal(1); B = normal(2); C = normal(3);
D = -dot(normal,pointA);
xLim = [min(x) max(x)];
yLim = [min(y) max(y)];
[Y,X] = meshgrid(yLim,xLim);
Z = (A * X + B * Y + D)/ (-C);
reOrder = [1 2  4 3];
figure();patch(X(reOrder),Y(reOrder),Z(reOrder),'r');
grid on;
alpha(0.3);
``````
• why do you use reOrder? @krishna-chaitanya – Jamais avenir Sep 4 '17 at 6:50