load('V1_in.mat')
[~,~,V]=svd( V_1-mean(V_1));
N=V(:,3)
calculate the normal for a plane passing through more than three points
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Alberto Acri
el 29 de Sept. de 2023
Hi! I have a plane passing through three points (triangular plane) and from which I determine the normal.
P = [ 0.034488 0.036484 0.006912; ...
0.019104 0.055041 0.047894; ...
-0.008596 0.123650 0.033786];
N = cross(P(1,:) - P(2,:), P(3,:) - P(2,:));
N = N/norm(N);
Is it possible to do the same thing with a circular plane ('V1_in')?
- If it is not possible to do this, how can I create the matrix equal to 'P' using the 'V1_in' plane?
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Respuesta aceptada
Bruno Luong
el 29 de Sept. de 2023
1 comentario
Bruno Luong
el 29 de Sept. de 2023
% Check againts other method for 3 points
P = [ 0.034488 0.036484 0.006912; ...
0.019104 0.055041 0.047894; ...
-0.008596 0.123650 0.033786];
N = cross(P(1,:) - P(2,:), P(3,:) - P(2,:));
N = N/norm(N)
[~,~,V]=svd( P-mean(P));
N=V(:,3)% opposite sign, which is arbitrary choice for a 2D plane
Más respuestas (3)
Torsten
el 29 de Sept. de 2023
Editada: Torsten
el 29 de Sept. de 2023
If the points in V1_in.mat all lie in a common plane, you can arbitrarily pick three points and define these points as P.
If the points are only "approximately" in a common plane, you have to determine this plane via regression (like @Bruno Luong did).
0 comentarios
Matthew Blomquist
el 29 de Sept. de 2023
Hi Alberto,
If you think of the circular plane as a collection of points with coordinates (x, y, z), you can create a bunch of "triangular planes" by selecting any three coordinates to create a triangle. If all of the coordinates lie in the same plane, computing the normal of any triangular plane will be the same as computing the normal of the circular plane.
So, you can use the same code, but substitute three points from the circular plane (in V1_in) to your P matrix. Also, I often use the functions "patch" and "quiver3" to help visualize the normals.
Hope that helps!
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Matt J
el 30 de Sept. de 2023
Editada: Matt J
el 30 de Sept. de 2023
Use planarFit() from this FEX package,
fitObj=planarFit(V_1')
fitObj =
planarFit with properties:
normal: [0.2147 -0.1801 0.9599]
distance: 82.5216
[hL,hD]=plot(fitObj); %Visualize the fit
legend([hL,hD],'Plane fit', 'XYZ samples', 'Location','northoutside','FontSize',15);
axis padded;
view(-70,15);drawnow
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